JP2013110317A - Capacitor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a capacitor device which prevents looseness of capacitor bodies housed in housing parts of a housing case and forms a clearance having a uniform width between inner peripheral surfaces of the housing parts and outer peripheral surfaces of the capacitor bodies.SOLUTION: A capacitor device has a housing case 3 where housing parts 5, each of which has a shape for fitting into an appearance shape of the capacitor body 2 and houses the capacitor body 2, are formed. An inner peripheral surface of each housing part 5 is formed into a taper surface 10 which gradually narrows toward a bottom surface thereof.

Description

  The present invention relates to a capacitor device having a storage case in which a storage portion for storing the capacitor body from an opening is formed in a shape that matches the external shape of the capacitor body.

  Conventionally, there is a capacitor mounting device that allows a capacitor to be inserted into a plurality of holes opened in a metal block. In such a capacitor mounting device, the inner diameter of the hole of the metal block is slightly larger than the diameter of the capacitor. In addition, a grease compound having excellent heat transfer and relatively high viscosity is filled between the outer peripheral surface of the capacitor and the inner wall of the hole (see, for example, Patent Document 1).

Japanese Utility Model Publication No. 6-62527

  However, in the capacitor mounting device (capacitor device) described in Patent Document 1, since the inner diameter of the hole is larger than the diameter of the capacitor, the capacitor is placed in the hole (housing portion) of the metal block (housing case). When the capacitor is inserted into the hole, the capacitor is wobbled inside the hole, and a predetermined part of the capacitor is in contact with the inner peripheral surface of the hole, and the other part is separated from the inner peripheral surface of the hole, and the outer periphery of the capacitor There is a problem that a gap having a uniform width cannot be ensured between the surface and the inner wall of the hole, and filling spots are generated in the grease compound to be filled.

  The present invention has been made paying attention to such problems, and prevents wobbling of the capacitor main body stored in the storage portion of the storage case, and the inner peripheral surface of the storage portion and the outer peripheral surface of the capacitor main body. An object of the present invention is to provide a capacitor device capable of forming a gap having a uniform width therebetween.

In order to solve the above problems, the capacitor device of the present invention is:
A capacitor device having a storage case in which a storage portion for storing the capacitor body is formed in a shape that matches the external shape of the capacitor body,
The inner peripheral surface of the storage portion is a tapered surface that narrows toward the bottom surface.
According to this feature, the bottom side of the capacitor body is positioned by a tapered surface that narrows the inner peripheral surface of the storage unit in a state where the opening side of the storage unit is enlarged to facilitate the insertion of the capacitor body into the storage unit. Therefore, the capacitor main body stored in the storage portion of the storage case can be prevented from wobbling, and a uniform width gap can be formed between the inner peripheral surface of the storage portion and the outer peripheral surface of the capacitor main body. When the resin material is filled, the resin material to be filled can be uniformly filled without causing spots.

The capacitor device of the present invention is
The inner peripheral surface of the storage portion is provided with a plurality of convex portions that protrude toward the capacitor main body and are evenly arranged in the circumferential direction of the inner peripheral surface of the storage portion.
According to this feature, the capacitor body is held at the central position of the storage portion by the convex portion on the inner peripheral surface of the storage portion, and the circumferential direction is between the inner peripheral surface of the storage portion and the outer peripheral surface of the capacitor body. A gap having a uniform width can be formed.

The capacitor device of the present invention is
The storage case is formed with a plurality of storage portions, and the storage case is formed with a communication portion that allows adjacent storage portions to communicate with each other.
According to this feature, when each storage unit is filled with a resin material, the resin material filled in the predetermined storage unit is moved to the adjacent storage unit via the communication unit. The amount of the resin material to be filled can be made uniform. Furthermore, after the resin material is cured, the resin material filled in the respective storage portions can be integrated to improve the holding strength of the capacitor body.

The capacitor device of the present invention is
A convex portion protruding toward the capacitor main body is provided on the bottom surface of the storage portion.
According to this feature, the height position in the storage portion of the capacitor body can be determined by the convex portion on the bottom surface of the storage portion. Further, a gap filled with the resin material can be formed between the bottom surface of the capacitor body and the bottom surface of the storage portion, and when the resin material is filled, the bottom surface of the capacitor body and the bottom surface of the storage portion can be formed. It is possible to prevent the resin material from being retained in between, and to prevent air from being accumulated.

It is a perspective view which shows the capacitor | condenser apparatus of 2 continuous lines in an Example. It is a perspective view which shows a capacitor | condenser main body and a storage case. It is a top view which shows the state which accommodated the capacitor | condenser main body in the storage case. It is a top view which shows the state which attached the center guide. It is a top view which shows the state which attached the bus-bar and a circuit board. It is an AA crossing top view which shows the storage case in FIG. It is a bottom view which shows a capacitor | condenser apparatus. It is a vertical side view which shows a storage case. It is a vertical side view which shows the storage case of the state which accommodated the capacitor | condenser main body. It is a top view which shows the terminal part of a capacitor | condenser main body. It is a vertical side view which shows the storage case in a modification.

  EMBODIMENT OF THE INVENTION The form for implementing the capacitor | condenser apparatus which concerns on this invention is demonstrated below based on an Example.

  The capacitor device according to the embodiment will be described with reference to FIGS. Reference numeral 1 in FIG. 1 denotes a capacitor device to which the present invention is applied. In the present embodiment, two capacitor devices 1 are connected to each other in the vertical direction. In addition, this capacitor | condenser apparatus 1 is mainly mounted and used for apparatuses, such as a vehicle.

  As shown in FIGS. 2 and 6, one capacitor device 1 is configured such that five (a plurality of) capacitor bodies 2 are integrally stored in a storage case 3. In this embodiment, an electric double layer capacitor is used for the capacitor body 2. The capacitor body 2 has a cylindrical shape, and a sealing plate 6 at the upper end of each capacitor body 2 is provided with terminal portions 4 for anode and cathode. In addition, the storage case 3 is provided with five (a plurality of) storage portions 5 for storing the capacitor main bodies 2, and the storage case 3 is opened at the upper side thereof, and the storage case 3 has five openings through the opening 9. The storage unit 5 is exposed to the outside.

  The storage case 3 is made of resin in which the five storage portions 5 are integrally molded. As the resin material constituting the storage case 3, a thermoplastic resin is used, and for example, polyethylene, polypropylene, polyethylene terephthalate, polybutylene terephthalate, nylon, polyphenylene sulfide, acrylic, polycarbonate, or the like is used. Moreover, the glass fiber etc. can be added to various resin materials as an additive, and the intensity | strength and heat resistance of the storage case 3 can also be improved.

  The storage case 3 is formed by resin molding in which a resin material is poured into a mold. Therefore, the storage case 3 can be easily mass-produced, and the capacitor device 1 can be manufactured at a low cost.

  Further, the five storage portions 5 of the storage case 3 are arranged in an annular shape in plan view with their longitudinal directions facing the same direction. Furthermore, a hollow portion 7 is formed in the central portion of the storage portion 5 arranged in an annular shape to release hydrogen gas generated in the capacitor body 2 described later. Each storage portion 5 has a cylindrical shape that conforms to the shape and dimensions of the capacitor body 2, and each storage portion 5 has a bottomed cylindrical shape with one end opened and the other end closed.

  As shown in FIG. 2, the upper portion side of the storage portion 5 extends upward to form a wall portion 8. The wall portion 8 is erected so as to surround the outer periphery of the arrangement shape according to the arrangement shape of the five storage portions 5. And the circuit which can arrange | position the circuit board 19 (circuit part) etc. which provided the bus-bar 18 (connecting member) and balance circuit etc. which mutually connect the terminal part 4 of each capacitor | condenser main body 2 mentioned later by this wall part 8 etc. An arrangement portion 20 is formed (see FIG. 5).

  Further, an upper side nut holding portion 14 for holding a nut (not shown) to which a bolt (not shown) for fixing the capacitor device 1 to another member is screwed is provided on the side peripheral surface of the upper portion of the storage portion 5. Is formed. Furthermore, a lower nut holding portion 15 is formed on the side peripheral surface of the lower portion of the storage portion 5. These upper and lower nut holding portions 14 and 15 are configured to provide a space for holding the nut using a valley between the storage portions 5.

  In addition, it is possible to fix the capacitor device 1 to a housing or the like of the device using nuts (not shown) held by the upper and lower nut holding portions 14 and 15 of the capacitor device 1. In this embodiment, the two capacitor devices 1 are arranged up and down, but the two capacitor devices 1 are arranged adjacent to each other on the left and right sides, and the upper and lower nut holding portions 14 and 15 of each capacitor device 1 are arranged. Each capacitor | condenser apparatus 1 can also be connected using the hold | maintained nut.

  As shown in FIGS. 3, 7, and 8, a lead-out hole 16 penetrating toward the hollow portion 7 in the central portion of the storage portion 5 that is annularly formed is formed in the central portion on the upper side of the storage case 3. Thus, a gas generated in the capacitor body 2 described later is led out toward the cavity 7 described above.

  As shown in FIG. 8, the inner peripheral surface of the storage portion 5 is a tapered surface 10 that narrows toward the bottom surface. The inclination θ of the tapered surface 10 in this embodiment is about 1.0 degree. The inclination θ of the tapered surface 10 may be any angle as long as it is in the range of about 0.3 to 5.0 degrees. A tapered surface 12 is also formed on the outer peripheral surface of the storage portion 5, and the inclination θ ′ of the tapered surface 12 is formed to be about 0.8 degrees or more.

  Further, as shown in FIG. 9, the inner diameter of the storage portion 5 is slightly larger than the outer diameter of the capacitor body 2 on the opening side, and is substantially the same as the outer diameter of the capacitor body 2 on the bottom side. It has become. Further, as will be described later, a gap 11 is formed between the inner peripheral surface of the storage portion 5 and the outer peripheral surface of the capacitor body 2. The gap 11 is filled with the resin material 17. It has come to be. In addition, the dimension S on the opening side of the gap portion 11 is set to about 0.5 to 3.0 mm in consideration of heat conductivity and resin material filling efficiency.

  The inner peripheral surface of the storage portion 5 is a tapered surface 10 that narrows toward the bottom surface, so that the opening side of the storage portion 5 is enlarged to facilitate the insertion of the capacitor body 2 into the storage portion 5. The bottom side of the main body 2 is positioned by a tapered surface 10 that narrows the inner peripheral surface of the storage portion 5 to prevent the capacitor main body stored in the storage portion 5 of the storage case 3 from wobbling. A gap portion 11 having a uniform width can be formed between the inner peripheral surface of the capacitor body 2 and the outer peripheral surface of the capacitor body 2. When the resin material 17 is filled in the gap portion 11, It is possible to fill uniformly without causing spots.

  As shown in FIGS. 3 and 8, three ribs 13 (projections) that protrude toward the capacitor body 2 and extend in the vertical direction are formed on the inner peripheral surface of the storage portion 5. The ribs 13 are arranged uniformly in the circumferential direction of the inner peripheral surface of the storage unit 5, and the protruding amount of the ribs 13 increases from the bottom side of the storage unit 5 toward the opening side. Further, since the rib 13 extends over the entire length from the opening side to the bottom side of the storage portion 5, when the capacitor main body 2 is stored in the storage portion 5, the rib 13 extends over the entire length. 2 is in contact with the outer peripheral surface.

  When the capacitor main body 2 is stored in the storage portion 5, the three ribs 13 are brought into contact with the capacitor main body 2 from three directions so that the capacitor main body 2 is held at the central position of the storage portion 5. Thus, a gap 11 having a uniform width in the circumferential direction can be formed between the inner peripheral surface of the storage portion 5 and the outer peripheral surface of the capacitor body 2. The ribs 13 are desirably arranged evenly in the range of 2 to 6 in the circumferential direction.

  In the present embodiment, the rib 13 on the inner peripheral surface of the storage portion 5 has substantially the same length as the vertical dimension of the capacitor body 2. In addition, the vertical dimension of the rib 13 may be formed over the entire length from the opening to the bottom of the storage portion 5, or over a range of about two thirds downward from the opening of the storage portion 5. You may make it form.

  As shown in FIG. 6, the storage case 3 is formed with a connecting portion 39 that connects adjacent storage portions 5 to each other. Further, as shown in FIG. 2 and FIG. 8, a cutout portion 21 (communication portion) that is cut out from the opening over a predetermined length downward is formed at the upper portion of the connection portion 39. . The adjacent storage portions 5 are communicated with each other by the cutout portion 21.

  As described above, the inner peripheral surface of the storage portion 5 is a tapered surface 10, and the upper portions of the storage portion 5 are close to each other so that the thickness of the connecting portion 39 (see FIG. 6) is thin. Therefore, it is easy to form the notch 21 by notching downward from the opening. In addition, since the site | part where the thickness of the upper part side of the connection part 39 of the accommodating part 5 is thin easily breaks, damage to the connection part 39 can be prevented by notching this site | part by the notch part 21, and The storage parts 5 are brought close to each other, so that the width dimension of the storage case 3 can be reduced, and the storage efficiency is improved.

  In addition, by forming the notch portion 21 that communicates between the storage portions 5, as will be described later, when the resin material 17 is filled in each storage portion 5, the resin material 17 that fills the predetermined storage portion 5. Is moved to the adjacent storage portions 5 through the notches 21, and the amount of the resin material 17 filled in each storage portion 5 can be equalized. Furthermore, after the resin material 17 is cured, the resin material 17 filled in each storage portion 5 is integrated, and the holding strength of the capacitor body 2 can be improved.

  Further, a chevron portion 22 (convex portion) is formed on the bottom surface of the storage portion 5 so that the central portion rises and protrudes into a chevron shape. When the capacitor body 2 is stored in the storage portion, the bottom surface of the capacitor body 2 is brought into contact with the chevron portion 22. By doing in this way, the height position in the storage part 5 of the capacitor | condenser main body 2 can be decided by the mountain-shaped part 22 of the bottom face of the storage part 5. FIG.

  Further, the chevron portion 22 can form a gap filled with the resin material 17 between the bottom surface of the capacitor body 2 and the bottom surface of the storage portion 5. This gap is formed so that the vertical width is widened toward the outside. When the resin material 17 is filled, the resin material 17 is retained between the bottom surface of the capacitor body 2 and the bottom surface of the storage portion 5. It is possible to prevent air retention. In addition, the protrusion dimension T of the mountain-shaped portion 22 is about 0.2 to 1.0 mm.

  As shown in FIGS. 2 and 3, when assembling the capacitor device 1, each capacitor body 2 is first inserted into the storage portion 5 through the opening 9 at the top of each storage case 3. The capacitor body 2 is guided and inserted in the central direction of the storage portion 5 by the tapered surface 10 of the storage portion 5 on the opening 9 side of the upper portion of each storage case 3. When the capacitor body 2 is stored in the storage unit 5, it is gradually inserted into the storage unit 5 with a predetermined pressing force. Then, the bottom portion of the capacitor body 2 is positioned at a predetermined position of the storage portion 5 by the rib 13. The process of storing each capacitor body 2 in each storage unit 5 is the storing process in this embodiment.

  Further, the bottom surface of the capacitor body 2 comes into contact with the mountain-shaped portion 22 on the bottom surface of the storage portion 5, and the height position of the capacitor body 2 is adjusted. The capacitor main body 2 stored in the storage unit 5 is in a state where the outer peripheral surface thereof is covered with the storage unit 5. As shown in FIG. 6, the entire circumference of the plurality of storage portions 5 has a uniform thickness along the outer peripheral surface of the capacitor body 2.

  As shown in FIG. 4, a center guide 23 (element member) is attached so as to cover the five capacitor bodies 2 stored in the storage unit 5 from above. The center guide 23 is a resin-made plate member having a substantially star shape whose outer peripheral edge is substantially the same as the overall shape of the five storage portions 5 combined. In addition, resin which comprises this center guide 23 is resin similar to the storage case 3 mentioned above.

  In this embodiment, the center guide 23 is attached to the capacitor body 2 after the capacitor body 2 is stored in the storage portion 5. However, after the center guide 23 is attached to the capacitor body 2, the center guide 23 is attached to the storage portion 5. The capacitor body 2 may be accommodated.

  Further, as shown in FIG. 9, a bent piece 24 bent downward is formed at the edge of the center guide 23, and the bent piece 24 is brought into contact with the inner peripheral surface of the storage portion 5, The guide 23 is positioned. Further, the center guide 23 is formed with an insertion hole 26 through which the terminal portion 4 of the capacitor body 2 is inserted.

  As shown in FIG. 10, the sealing plate 6 of the capacitor body 2 is provided with a terminal block portion 27 on which the terminal portion 4 is disposed. The terminal block 27 is provided with the anode and cathode terminal portions 4 and is engaged with the engaged holes 28 (engaged portions) of the center guide 23 between the terminal portions 4. An engaging convex portion 29 (engaging portion) is convexly provided. The engagement convex portion 29 is provided at a position slightly deviated from the center C of the sealing plate 6, that is, the longitudinal axis C of the capacitor body 2.

  As shown in FIG. 4, when the center guide 23 is attached to the capacitor body 2, the engaging convex portion 29 is engaged with the both terminal portions 4 inserted in the insertion holes 26 of the center guide 23. The direction of the capacitor body 2 that can be engaged with the joint hole 28 is specified. That is, the engaging protrusion 29 causes the capacitor body 2 to have non-rotational symmetry with the longitudinal axis as the center C (see FIG. 10), and the anode terminal portion 4 and the cathode terminal portion of the capacitor body 2 4 can be prevented from being reversed and attached.

  Further, the upper surface of the terminal block portion 27 of the sealing plate 6 of the capacitor body 2 is brought into contact with the lower surface of the center guide 23 so that the height positions of the capacitor bodies 2 are unified. In addition, a convex portion (not shown) protruding downward is provided on the lower surface of the center guide 23, and this convex portion is brought into contact with the upper surface of the sealing plate 6 so that the height positions of the capacitor bodies 2 are unified. Also good.

  Further, when the center guide 23 is attached to the capacitor body 2, the five capacitor bodies 2 are integrated with each other, and the relative positions of the capacitor bodies 2 are defined. By doing so, the engaging protrusions 29 of the capacitor body 2 are engaged with the engaged holes 28 of the center guide 23, and the respective storage portions 5 are positioned in a state where each capacitor body 2 is positioned by the center guide 23. The terminal portion 4 can be placed in a specific arrangement, and the center guide 23 can easily align the terminal portion 4 of the capacitor body 2.

  And each terminal part 4 of the capacitor | condenser main body 2 protrudes upward from the insertion hole 26 of the center guide 23, the bus-bar 18 (connection member) is connected to this terminal part 4, and each capacitor | condenser main body 2 is electrically connected in series. Connected to. For the connection between the terminal portion 4 and the bus bar 18, screw connection, laser connection, ultrasonic connection, or the like is used.

  Further, a circuit board 19 provided with a balance circuit or the like disposed between the bus bars 18 is attached. On the upper surface of the center guide 23, a protruding portion 31 (engaged portion) that is engaged with a hole 30 formed in the bus bar 18 and an engagement hole (not shown) on the lower surface of the circuit board 19 is projected. The bus bar 18 and the circuit board 19 are positioned by the protruding bar 31.

  Further, on the upper surface of the center guide 23, a bus bar engaging convex portion 40 (engaged portion) on which the bus bar 18 is engaged along the edge portion (engaging portion) protrudes, and the edge of the circuit board 19 A hook-like locking claw 41 (engaged portion) that is locked to the portion (engagement portion) is provided. The bus bar 18 and the circuit board 19 are positioned by the bus bar engaging protrusions 40 and the locking claws 41. And the center guide 23, the bus bar 18, and the circuit board 19 are integrated, and vibration resistance improves. The balance circuit of the circuit board 19 is connected to each bus bar 18.

  As described above, since the relative positions of the five capacitor bodies 2 are defined, it becomes easy to connect the bus bar 18, the circuit board 19, and the like to the terminal portion 4 of the capacitor body 2. Can be simplified. The circuit board 19 is coated with an epoxy resin, a urethane resin, or the like to prevent corrosion. In addition, the fixing of each member such as the bus bar 18 and the circuit board 19 can be improved, and this is particularly effective when the capacitor device 1 is used for a vehicle application to which vibration is applied.

  Further, the insertion hole 26 of the center guide 23 can be used as an engaged portion, the terminal portion 4 of the capacitor body 2 can be used as the engaging portion, and each terminal portion 4 of each capacitor body 2 can be electrically connected. Each capacitor body 2 is integrally connected by the center guide 23 and the bus bar 18 by using the bus bar 18 connected to the capacitor bar 1, and the capacitor body 2 can be easily stored in each storage portion 5. Manufacturing work can be simplified. The process of attaching the center guide 23 to the capacitor body 2 is an integration process in the present embodiment.

  As shown in FIG. 9, a fluid resin material 17 is filled in the gap portion 11 formed between the inner peripheral surface of the storage portion 5 and the outer peripheral surface of the capacitor body 2. The center guide 23 is formed with a filling hole 33 used when the resin material 17 is filled. A filling pipe (not shown) or the like is inserted into the center guide 23 from the filling hole 33 toward the gap portion 11. Fill material 17. The resin material 17 is a thermosetting resin such as an epoxy resin or a urethane resin which is cured by causing a polymerization reaction by heating or mixing two liquids.

  Further, the resin material 17 is filled in the entire portion L of the gap portion 11 between the outer peripheral surface of the capacitor body 2 and the inner peripheral surface of the storage portion 5. In the present embodiment, the resin material 17 is filled in the entire portion L of the gap 11, but the portion H that is about half of the gap 11 may be filled. Can be changed as appropriate.

  Then, the resin case 17 is heated to cure the resin material 17 in a state where the resin material 17 is filled in the gap portion 11 of the storage portion 5. The heating temperature in this resin curing step is set to 200 degrees or less and within 5 minutes so that excessive heat is not applied to the capacitor body 2 to cause deterioration of characteristics.

  By doing so, it is possible to improve the holding strength of the capacitor body 2 by curing the resin material 17 and to prevent the capacitor body 2 from being corroded. After engaging and integrating with the center guide 23 and the relative positions of the terminal portions 4 of each capacitor body 2 are positioned by the center guide 23, the inner peripheral surface of the storage portion 5 and the capacitor in the resin curing step. Since the resin material 17 between the outer peripheral surface of the main body 2 is cured, even if the terminal portions 4 of the capacitor main bodies 2 are connected to the bus bar 18, the circuit board 19, or the like, distortion or stress is applied to the terminal portions 4. Therefore, the capacitor device 1 that can withstand long-term use can be manufactured. That is, it is preferable to harden the resin material after the step of generating stress on the terminal portion 4 and the like.

  Further, the outer peripheral surface of the capacitor main body 2 is bonded to the inner peripheral surface of the storage portion 5 via the resin material 17, and the capacitor main body 2 is firmly held in the storage portion 5 and is attached to the storage case 3 through the resin material 17. Heat transfer is improved. Furthermore, heat dissipation is enhanced, and the impact force from the outside on the capacitor body 2 is relieved by the resin material 17.

  Further, after the terminal portions 4 of the capacitor main bodies 2 are electrically connected to an electric circuit or the like in the integration step described above, the inner peripheral surface of the storage portion 5 and the capacitor main body 2 are fixed in the resin curing step. Since the resin material 17 between the outer peripheral surface and the outer peripheral surface is cured, the terminal portion 4 is not required to be distorted or stressed, and the capacitor device 1 that can withstand many years of use can be manufactured.

  In addition, by using a thermosetting resin that causes a polymerization reaction by heating or the like as the resin material 17 filled in the storage unit 5, the work can be performed while controlling the cured state of the resin material 17. Can be positioned relative to each other, and the capacitor body can be inserted into the storage portion 5 when the capacitor body 1 is fluid. Can be easily manufactured.

  The resin constituting the storage case 3 is a resin having affinity with the resin material 17 filled in the storage portion 5, and when the resin material 17 is cured in the resin curing process, the resin material 17 And the storage portion 5 of the resin storage case 3 are firmly coupled, and the holding strength of the capacitor body 2 can be improved.

  In this embodiment, after the capacitor main body 2 is stored in the storage portion 5, the storage portion 5 is filled with the resin material 17. However, other modes may be used. After the resin material 17 is poured, the resin material 17 may be pushed and the capacitor main body 2 stored in the storage portion 5 so that the gap portion 11 is filled with the resin material 17.

  Further, after a half amount of the resin material 17 has been poured into the storage portion 5 first, the resin material 17 is pushed apart to store the capacitor body 2 in the storage portion 5, and then the remaining amount of the resin material 17 is stored in the storage portion. 5 may be filled with the resin material 17 in the gap 11.

  Furthermore, in the present embodiment, an integration process for attaching the center guide 23 to the capacitor body 2 is performed before the housing portion 5 is filled with the resin material 17, but the housing portion 5 is filled with the resin material 17. After that, the center guide 23 may be attached to the capacitor body 2 and the integration process may be performed. Even in such a case, the timing at which the resin material 17 is cured may be after the integration step.

  Further, in this embodiment, the resin material 17 is cured by heating, and this heating process is a resin curing process. For example, the resin material 17 that is cured after a predetermined time after mixing the two liquids is used. When used, the step of waiting for a predetermined time until the filled resin material 17 is cured is the resin curing step.

  Further, the opening 9 of the storage case 3 is closed by the closing plate 32. On the upper surface side of the center guide 23, a protruding bar 34 that protrudes upward and contacts the lower surface of the closing plate 32 to align the closing plate 32 is provided. In a state where the position of the closing plate 32 is specified by the protruding bar 34, the peripheral edge of the closing plate 32 and the wall portion 8 of the storage case 3 are sealed by means such as ultrasonic welding.

  Further, inside the capacitor body 2, a leakage current flows during use, and hydrogen gas may be generated due to this leakage current. As shown in FIG. 10, a pressure release mechanism 25 (pressure release means) that releases the pressure of hydrogen gas generated in the capacitor body 2 is provided on the upper surface of the sealing plate 6 of the capacitor body 2. In the state where the capacitor body 2 is stored in the storage portion 5, the pressure release mechanism 25 is arranged on the center side of the storage case 3 (see FIG. 3).

  As shown in FIGS. 4 and 9, an opening hole 35 is formed in the center guide 23 at a position corresponding to the pressure releasing mechanism 25. Therefore, the gas released from the pressure release mechanism 25 is not blocked by the center guide 23, and the gas can be safely released from the opening hole 35.

  Further, the gas released from the pressure release mechanism 25 of each capacitor body 2 flows from the opening hole 35 to the upper surface side of the center guide 23. A passage hole 36 through which gas passes is formed at the center portion of the center guide 23 at a position corresponding to the lead-out hole 16 of the storage case 3 described above, and the gas that has flowed to the upper surface side of the center guide 23. The lead-out hole 16 of the storage case 3 is guided.

  As shown in FIGS. 7 and 9, the lead-out hole 16 is provided at a position surrounded by the storage portion 5 arranged in an annular shape. The lead-out hole 16 has a cylindrical portion 37 having a cylindrical shape that protrudes toward the cavity portion 7 on the lower side. Furthermore, a funnel-shaped funnel portion 38 that is inclined toward the cylindrical portion 37 is provided above the cylindrical portion 37. The funnel-shaped funnel portion 38 drains the infiltrated water better.

  Further, when gas is generated inside the capacitor body 2 and the pressure release mechanism 25 is activated, the gas is led out from the outlet hole 16 in the central portion of the storage case 3 toward the cavity portion 7. . Further, the lower side of the cavity 7 is open to the outside, and gas is discharged from the cavity 7 to the outside of the storage case 3.

  By doing so, the lead-out hole 16 for leading the gas released from the pressure release mechanism 25 of the capacitor body 2 to the outside of the storage case 3 is surrounded by the plurality of storage portions 5 integrally connected. The lead-out hole 16 is arranged on the back side (the upper side of the storage case 3) of the cavity portion 7 formed by the plurality of storage portions 5, and the lead-out hole 16 is not exposed to the outside of the storage case 3. Thus, external dust and water can be prevented from entering the storage case 3 from the outlet hole 16.

  As shown in FIG. 6, at least the cavity 7 side of the storage portion 5 has a uniform thickness along the outer peripheral surface of the capacitor body 2. Therefore, it becomes possible to arrange a plurality of storage parts 5 close to each other, to reduce the size and weight of the storage case 3, and to provide a sufficient volume for the gas led out from the outlet hole 16 to spread. The cavity 7 can be formed, and the gas can be safely released from the outlet hole 16.

  In addition, the plurality of storage portions 5 are arranged in a ring shape, and a lead-out hole 16 is provided in the central portion of the plurality of storage portions 5, whereby the pressure release mechanism of the capacitor body 2 stored in each storage portion 5. The distance from 25 to the lead-out hole 16 is the same, and the released gas can reach the lead-out hole 16 even if the gas is released from the pressure release mechanism 25 of any capacitor body 2. The gas that has passed through the lead-out hole 16 is discharged from the capacitor body 1 to the outside through a gap (not shown) provided between the capacitor bodies 1 connected vertically.

  In addition, since the storage case 3 is made of a resin in which a plurality of storage portions 5 are integrally molded, the degree of blockage in the storage case 3 is increased, and external dust and water from other than the lead-out hole enter the storage case. It can be prevented from entering.

  In addition, since the storage case 3 is sealed at its opening side by a closing plate 32 and only the lead-out hole 16 at the center of the storage case 3 is opened, the capacitor device 1 is mounted on a device such as a vehicle. In such a case, even if the vehicle is submerged, water does not enter the capacitor device 1 unless the water reaches the outlet hole 16 of the storage case 3.

  In the present embodiment, three ribs 13 (projections) extending in the vertical direction are formed on the inner peripheral surface of the storage portion 5. However, as in the modification shown in FIG. You may make it not form the rib 13 in a surrounding surface. Even in such a storage case 3, the inner peripheral surface of the storage portion 5 is a tapered surface 10 that narrows toward the bottom surface, so that the opening side of the storage portion 5 is enlarged and the capacitor body 2 is stored in the storage portion. 5, the bottom side of the capacitor main body 2 is positioned by the tapered surface 10 that narrows the inner peripheral surface of the storage portion 5, and the capacitor main body stored in the storage portion 5 of the storage case 3. The wobbling can be prevented, and the gap 11 having a uniform width can be formed between the inner peripheral surface of the storage portion 5 and the outer peripheral surface of the capacitor body 2.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above embodiment, an electric double layer capacitor is exemplified as the capacitor, but the capacitor to which the present invention is applied is not limited to this, and can be applied to various capacitors such as an electrolytic capacitor and an electrochemical capacitor, and a capacitor.

  Moreover, in the said Example, although the cylindrical capacitor | condenser main body 2 was illustrated, this invention is applicable not only to this but non-cylindrical capacitor | condenser main bodies, such as a square shape. In addition, if it is a square-shaped capacitor | condenser main body, what is necessary is just to adapt to the square shape and to make the storage part of a storage case into a square cylinder shape.

  Moreover, in the said Example, although the five storage parts 5 are formed in cyclic | annular form with respect to one storage case 3, the number and arrangement | positioning form of these storage parts 5 are not specifically limited, At least 2 Individual or three storage units 5, or six or seven or more storage units 5 may be formed, and the storage units 5 may be arranged in one or a plurality of rows.

DESCRIPTION OF SYMBOLS 1 Capacitor apparatus 2 Capacitor main body 3 Storage case 4 Terminal part 5 Storage part 6 Sealing plate 7 Cavity part 8 Wall part 9 Opening part 10 Tapered surface 11 Gap part 12 Tapered surface 13 Rib (convex part)
14, 15 Nut holding part 16 Lead-out hole 17 Resin material 18 Bus bar (connection member)
19 Circuit board (circuit part)
20 Circuit arrangement part 21 Notch part (communication part)
22 Mountain-shaped part (convex part)
23 Center guide (elements)
24 Bending piece 25 Pressure release mechanism (pressure release means)
26 Insertion hole 27 Terminal block 28 Engaged hole (engaged part)
29 Engagement convex part (engagement part)
30 hole 31 protruding rod (engaged part)
32 Blocking plate 33 Filling hole 34 Protruding rod 35 Opening hole 36 Passing hole 37 Cylindrical part 38 Funnel part 39 Connecting part 40 Bus bar engaging convex part (engaged part)
41 Claw (engaged part)

Claims (4)

A capacitor device having a storage case in which a storage portion for storing the capacitor body is formed in a shape that matches the external shape of the capacitor body,
The capacitor device according to claim 1, wherein an inner peripheral surface of the storage portion is a tapered surface that narrows toward the bottom surface.   The plurality of convex portions that protrude toward the capacitor main body and are uniformly arranged in a circumferential direction of the inner peripheral surface of the storage portion are provided on the inner peripheral surface of the storage portion. The capacitor device according to 1.   3. The storage case according to claim 1, wherein the storage case is formed with a plurality of storage portions, and the storage case is formed with a communication portion that allows adjacent storage portions to communicate with each other. Capacitor device.   4. The capacitor device according to claim 1, wherein a convex portion projecting toward the capacitor body is provided on a bottom surface of the storage portion. 5.

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