JP4377092B2 - Electrolytic capacitor element aging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolytic capacitor element aging device, and particularly to a technical field related to performing an aging process by heating a plurality of electrolytic capacitor elements attached to a holder and supplying a predetermined voltage. is there.
[0002]
[Prior art]
Conventionally, in the process of manufacturing an electrolytic capacitor, an aging treatment is performed to repair a partial breakdown of a dielectric oxide film generated during the manufacturing. In the case of aging treatment of an electrolytic capacitor, a large number of electrolytic capacitors are placed in a heating furnace while being held by a holder and heated, and a predetermined voltage is supplied to the held electrolytic capacitor (Japanese Patent Laid-Open No. Sho). 63-88816 gazette etc.).
[0003]
An example of the configuration of a conventional aging apparatus is shown in FIG. As shown in the figure, a large number of electrolytic capacitor elements 81 are provided with a main body portion 82 and a pair of lead wires 83, and are mounted in a state of being aligned with a long holding tool 84. Many holders 84 are attached to a rotating body (not shown). Then, while the rotating body is slowly rotated in the aging device, the inside of the device is heated and a predetermined voltage is supplied to the electrolytic capacitor element 81 attached to the holder 84 to perform aging. Is done.
[0004]
The holder 84 includes an insulating plate 85, and the electrolytic capacitor element 81 is attached so that a pair of lead wires 83 straddles the tip end side (left end side in FIG. 12) of the insulating plate 85. During aging, a leaf spring 87 provided on the clamping means 86 is sandwiched from both sides of the insulating plate 85. Thereby, an electrical conduction state is secured for the lead wire 83.
[0005]
[Problems to be solved by the invention]
At this time, heat should be applied only to the main body 82 of the electrolytic capacitor element 81, and it is not desirable that the holder 84 is heated. Therefore, it is conceivable to attach a heat insulating cloth 88 to the top surface of the clamping means 86 as shown in FIG. By configuring in this way, heating is mainly achieved on the main body portion 82 side than the heat insulating cloth 88.
[0006]
However, with the above configuration, it is not always possible to sufficiently insulate. That is, as shown in FIG. 13, the lead wire 83 is in contact with the insulating plate 85, and the plate spring 87 is in contact with the lead wire 83. For this reason, in this heat insulation cloth 88, the clearance gap S will be formed, and hot air will leak toward the base end part side of the insulating board 85. Therefore, there is a possibility that a problem due to hot air leakage occurs.
[0007]
The present invention has been made in view of the above circumstances, and has as one of its main objects to provide an electrolytic capacitor element aging device that can suppress various problems caused by heat leakage.
[0008]
[Means for solving the problems and effects thereof]
Characteristic means capable of achieving the above object will be described below. For each means, characteristic actions and effects are described as necessary.
[0009]
Means 1. A heating furnace for heating from the outer peripheral edge to the inside and a plurality of electrolytic capacitor elements consisting of a main body and a pair of lead wires extending from the main body can be mounted by straddling the lead wires. A plurality of holders provided with a long plate-like body that is formed, and clamping means that can be clamped so as to come into contact with the lead wire from both sides of the plate-like body, and the holder is rotated in the heating furnace. In an aging device for an electrolytic capacitor element provided with a rotational movement means, a heat insulating material having flexibility is attached to the clamping means, and the thermal insulation is in a state where the clamping means is in contact with the lead wire. An aging device for an electrolytic capacitor, wherein one end side of the material overlaps with a heat insulating material of an adjacent holder, and the other end side of the heat insulating material is in contact with the plate-like body.
[0010]
According to the means 1, in the heating furnace, the heating is performed from the outer peripheral edge side toward the inner side. A plurality of electrolytic capacitor elements composed of a main body and a pair of lead wires extending from the main body are attached by the lead wires straddling the plate-like body. Further, the holding tool is rotated and moved in the heating furnace by the rotation moving means in a state where the holding means is held so as to come into contact with the lead wire from both sides of the plate-like body. In such an aging device, a flexible heat insulating material is attached to the clamping means. And when the clamping means is in contact with the lead wire, that is, during aging, one end side of the heat insulating material overlaps with the heat insulating material of the adjacent holder, so basically the heat insulating material However, the main body side is mainly heated, and the opposite side is hardly heated. In particular, since the other end side of the heat insulating material is configured to contact the plate-like body, a gap is hardly formed between the other end side of the heat insulating material and the plate-like body, and heat leaks from the main body side. Hard to happen. As a result, various problems due to heat leakage can be suppressed.
[0011]
Mean 2. A heating furnace for performing heating from the outer peripheral edge side to the inside, a rotating shaft supported rotatably in the heating furnace, and a substantially disk shape provided at a distance from the rotating shaft; or A long wheel configured to be able to be mounted by straddling the lead wires with a plurality of electrolytic capacitor elements comprising a pair of substantially wheel-shaped rotating bodies and a pair of lead wires extending from the main body portion. A plurality of holding members that are provided at predetermined intervals so as to be opposed to each other on substantially the outer peripheral portions of the pair of rotating bodies, comprising a plate-like body and clamping means that can be clamped so as to come into contact with the lead wire from both sides of the plate-like body In an electrolytic capacitor element aging device comprising a tool, a flexible heat insulating material is attached to the holding means, and the holding means is in contact with the lead wire. One end is next With overlaps the insulation holder for aging device of the electrolytic capacitor, wherein the other end of the heat insulating material is configured to contact with the plate-like body.
[0012]
According to the means 2, in the heating furnace, the heating is performed from the outer peripheral edge side toward the inner side. In the heating furnace, a pair of approximately disc-shaped or approximately wheel-shaped rotating bodies provided at a distance from the rotation axis are rotated. A plurality of holders are attached at predetermined intervals so as to face each other on substantially the outer peripheral portions of the pair of rotating bodies. The holder includes a plate-like body and clamping means, and is attached to the plate-like body by straddling a plurality of electrolytic capacitor element lead wires including a main body portion and a pair of lead wires extending from the main body portion. . Further, both sides of the plate-like body are clamped by clamping means so as to come into contact with the lead wires. In such an aging device, a flexible heat insulating material is attached to the clamping means. And when the clamping means is in contact with the lead wire, that is, during aging, one end side of the heat insulating material overlaps with the heat insulating material of the adjacent holder, so basically the heat insulating material However, the main body side is mainly heated, and the opposite side is hardly heated. In particular, since the other end side of the heat insulating material is configured to contact the plate-like body, a gap is hardly formed between the other end side of the heat insulating material and the plate-like body, and heat leaks from the main body side. Hard to happen. As a result, various problems due to heat leakage can be suppressed.
[0013]
Means 3. The clamping means includes an elastic member that can contact the lead wire and can be electrically connected, and a support means that directly or indirectly supports the elastic member, and the heat insulating material has at least the other end side thereof. 3. The electrolytic capacitor element aging device according to claim 1 or 2, wherein the aging device is attached to the support means so as to extend beyond an elastic member.
[0014]
According to the means 3, the elastic member is directly or indirectly supported by the supporting means of the clamping means, and the elastic member comes into contact with the lead wire to achieve electrical conduction. Moreover, the heat insulating material is attached to the support means so that the other end side extends at least from the elastic member. For this reason, the clearance gap between a plate-shaped body and an elastic member becomes easy to be closed, and the heat leak from this clearance gap is suppressed more reliably.
[0015]
In addition, it is good also as "it is comprised so that the heat insulating material attached to one support means may consist of at least 2 sheets, and an adjacent heat insulating material may enter between the said heat insulating materials." By adopting such a configuration, it becomes difficult to form a gap between adjacent heat insulating materials even when the holding means is in an open state or a closed state, and it is possible to further suppress heat leakage. it can.
[0016]
Means 4. 4. The electrolytic capacitor element aging device according to any one of means 1 to 3, wherein the heat insulating material is constituted by a heat insulating cloth in which a metal coating is applied to the cloth.
[0017]
According to the means 4, since the heat insulating material is constituted by a heat insulating cloth in which a metal coating is applied to the cloth, it is easy to perform processing and the like, and the heat retaining effect is enhanced by radiant heat.
[0018]
Means 5. 5. The electrolytic capacitor element according to claim 1, wherein at least a portion of the heat insulating material that contacts the plate-like body on the other end side is made of an elastically compressible material. Aging device.
[0019]
According to the means 5, since at least the contact portion of the heat insulating material to the plate-like body is made of a material that can be elastically compressed and deformed, the sealability of the contact portion and its vicinity can be improved. It is done.
[0020]
Means 6. 6. The means according to claim 1, wherein a slit is formed at least in a portion corresponding to the lead wire in a contact portion of the heat insulating material to the plate-like body on the other end side. Electrolytic capacitor element aging device.
[0021]
According to the means 6, since the slit is formed at least in the portion corresponding to the lead wire in the contact portion of the heat insulating material to the plate-like body on the other end side, the lead wire enters the slit. The contact area with the plate-like body on the other end side of the heat insulating material is increased, and the gap is further narrowed. As a result, heat leakage is further suppressed.
[0022]
Mean 7 Any of means 1 to 6, wherein a fluff-like member is provided at least in a portion corresponding to the lead wire in a contact portion of the heat insulating material to the plate-like body on the other end side. 2. An aging device for electrolytic capacitor elements according to 1.
[0023]
According to the means 7, since the fluff-like member is provided at least in the part corresponding to the lead wire in the contact portion of the heat insulating material to the plate-like body on the other end side, the lead wire is fluffy. By entering between the members, the contact area between the other end side (including the fluffy member) of the heat insulating material and the plate-like body is increased, and the gap is further narrowed. As a result, heat leakage is further suppressed.
[0024]
Means 8. 8. The electrolytic capacitor element aging device according to any one of means 1 to 7, wherein the heating furnace is capable of deriving hot air from the outer peripheral edge side toward the inner side.
[0025]
According to the means 8, in the heating furnace, the hot air is led out from the outer peripheral side toward the inside, and the main body is heated by the hot air, but this hot air is difficult to leak from the heat insulating material, and the problem due to the hot air leakage. Can be suppressed.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment will be described with reference to the drawings.
[0027]
As shown in FIGS. 2 and 3, the aging apparatus 1 in the present embodiment includes a heating unit 2 and a transport unit 3. The conveying means 3 includes a bearing 4, and a rotating shaft 5 is rotatably supported on the bearing 4. A pair of wheel-like rotating bodies 8 for carrying a holder 7 for holding an electrolytic capacitor element (hereinafter simply referred to as “element”) 6 is attached to substantially both ends of the rotating shaft 5.
[0028]
These rotating bodies 8 rotate slowly based on the rotation of a drive motor (not shown). As shown in FIG. 6, the concave portions 9 and the convex portions 10 are alternately formed in a gear shape on the outer periphery of each rotating body 8.
[0029]
A plurality of (for example, about 60 to 100) long holders 7 are attached to the outer periphery of the rotating body 8 at predetermined intervals. The holder 7 is attached so as to be positioned corresponding to each concave portion 9 of the rotating body 8. The holder 7 includes a fixture 11 attached to the rotating body 8, and an insulating plate 12 as a long plate-like body attached to the fixture 11 and extending between the pair of rotating bodies 8. Yes. Details of the holder 7 will be described later.
[0030]
A heating furnace 21 that covers about 270 degrees from position A to position B in FIG. The heating furnace 21 surrounds the outer periphery of the transfer path of the holder 7 in an annular shape and is separated from the outside. The heating furnace 21 is supported concentrically with the rotary shaft 5 by a substantially wheel-shaped frame 22 (see FIG. 2) attached to the bearing 4.
[0031]
A blower 23 for sending hot air into the heating furnace 21 is attached to one end edge side (position A in FIG. 3) of the heating furnace 21 in the circumferential direction. The blower 23 includes a blower housing 25 that is connected to the heating furnace 21 and has a space 24 that extends into the heating furnace 21 and extends in parallel with the rotary shaft 5. A fan 26 and a heater 27 are provided in the space 24. In the heating furnace 21 and the blower housing 25, a partition wall 28 extending over the entire length is provided concentrically with the heating furnace 21, so that the heating furnace 21 and the blower housing 25 have a radially outward path 29 inside the heating furnace 21 and the blower housing 25. And the outer return path 30. Therefore, the hot air sent by the fan 26 and heated by the heater 27 flows in the forward path 29 in the counterclockwise direction in FIG. 3 and flows in the return path 30 near the position B at the end of the heating furnace 21, and then flows there. Flows in the clockwise direction and returns into the blower housing 25. Thus, the heating means 2 is comprised by the heating furnace 21, the air blower 23, etc. FIG.
[0032]
Next, the operation of the aging device 1 in the present embodiment will be briefly described. The rotating body 8 of the conveying means 3 is intermittently rotated slowly, for example, in the counterclockwise direction of FIG. And when the holder 7 attached to the outer periphery of the rotating body 8 comes to the position C (delivery part), taking out a large number of elements 6 held by the holder 7 and introducing new elements 6 to the holder 7. Supply is performed by a supply take-out device (not shown).
[0033]
In the heating furnace 21 and the blower housing 25, hot air heated by the heater 27 is circulated in the order of the forward path 29 → the end of the heating furnace 21 → the return path 30 → the blower housing 25. Further, the capacitor element 6 held by the holder 7 moves in the counterclockwise direction in FIG. 3 together with the holder 7 and is heated by hot air while passing through the forward path 29. At this time, a predetermined voltage is supplied to the terminal of each insulating plate 12 (holding tool 7) from the electrode terminal on the frame 22 (external) side, and with the rotation of the rotating body 8, Each holding tool 7 slides, and the electrode terminal which contacts is shifted one after another. During this time, a predetermined voltage is supplied via the holder 7 so that an aging process is performed.
[0034]
Next, details of the holder 7 for holding the element 6 will be described. As shown in FIGS. 4, 5, and 6, a pair of levers 31 are rotatably attached to the respective attachments 11 by pins 32 so as to sandwich the insulating plate 12 therebetween. A pair of spring holder supports 33 are attached to the tip of the lever 31 as support means extending substantially parallel to the insulating plate 12. A chuck 34 as a clamping means for gripping the element 6 is constituted by the lever 31 and the spring holder support 33 and the like. A spring holder 35 made of an insulating material is mounted in the recess on the insulating plate 12 side of the spring holder support 33. A leaf spring 36 as an elastic member made of a conductive material is attached in the central recess of the spring holder 35. A plurality of such leaf springs 36 are arranged so as not to contact each other in the extending direction of the spring holder support 35.
[0035]
As shown in FIG. 7, on one surface of each insulating plate 12, an electrode plate 41 extending substantially the entire length is provided. A plurality of electrode plates 42 are provided on the other surface of the insulating plate 12 at positions corresponding to the plate springs 36. Positive and negative terminals (not shown) are attached to the end of the insulating plate 12. One terminal is connected to the electrode plate 41, and the other terminal can be electrically connected to each electrode plate 42 via the element 6. In the present embodiment, for example, 80 elements 6 are held per holder 7.
[0036]
The electrode plates 41 and 42, the leaf spring 36, and the element 6 have a relationship as shown in FIG. That is, when the electrode plates 41 and 42 straddle a pair of lead wires 43 extending from the main body portion 6a of the element 6 over both ends of the insulating plate 12 and hold the lead wires 43 by the chuck 34, Each lead wire 43 is in contact with the corresponding electrode plate 41, 42 to form one electrical conduction circuit. At the same time, the upper end portion of the leaf spring 36 is in contact with the lead wire 43 and the lower end is in contact with the corresponding electrode plates 41 and 42 to form another electrical conduction circuit.
[0037]
As shown in FIGS. 5 and 6, a cam shaft 44 extending along the longitudinal direction of the insulating plate 12 is rotatably attached to the fixture 11. A cam 45 having a notch groove is attached to the cam shaft 44. A pair of rollers 46 that contact the cam 45 are attached to the lower ends of the levers 31. The upper ends of the pair of levers 31 are always closed, that is, the leaf spring 36 is in contact with the insulating plate 17.
[0038]
On the other hand, when the holder 7 comes to the supply position of the element 6, the cam shaft 44 is rotated by a known external drive device (not shown), and the notch groove of the cam 45 is engaged with the roller 46. To come. Then, the leaf | plate spring 36 will leave | separate from the insulating plate 12, and will be in the state which can supply the element 6 (refer FIG. 6). Then, after the element 6 is supplied, the camshaft 44 is rotated again by the driving device and returned to the original state. As a result, the gap between the lower ends of the pair of levers 31 is widened by the cam 45, so that the spring holder support 33 approaches the insulating plate 12 and the lead wire 43 is pressed by the plate spring 36. As a result, the holding of the element 6 and the electrical continuity of two paths between the lead wire 43 and the electrode plates 41 and 42 are achieved together.
[0039]
In the heating furnace 21, heat should be applied only to the main body 6 a of the element 6, and it is not desirable that the insulating plate 12 is heated. For this reason, in the present embodiment, as shown in FIG. 1, a heat insulating cloth 51 as a heat insulating material extending over the entire length of the spring holder support 35 is provided on the distal end surface (left end surface in the drawing) of the spring holder support 35. It is attached by a rivet 52. As the heat insulating cloth 51, for example, a cloth made of flame-retardant fiber and coated with aluminum foil on one surface of a highly airtight cloth and further coated with silicon is preferably used. However, any other material may be used.
[0040]
The heat insulating cloth 51 attached to one spring holder support 33 consists of two sheets, and the heat insulating cloth 51 attached to the other spring holder support 33 consists of one sheet. And between the two heat insulation cloths 51, the one heat insulation cloth of the holder 7 which adjoins has entered. In addition, one heat insulating cloth 51 enters between the two heat insulating cloths of the adjacent holder 7 on the opposite side.
[0041]
In the present embodiment, when the lead wire 43 is pressed and held by the chuck 34, that is, in a state of being held by the leaf spring 36 (during aging), as described above, One end side overlaps with the heat insulating cloth of the holder 7 adjacent thereto. Further, the other end side of the heat insulating cloth 51 is configured to contact the insulating plate 12. That is, the other end side of the heat insulating cloth 51 extends to the tip side from the leaf spring 36 and is in pressure contact with the insulating plate 12.
[0042]
Next, the operation and effect of the present embodiment configured as described above will be described.
[0043]
During the aging, one end side of the heat insulating cloth 51 overlaps with the heat insulating cloth of the adjacent holder 7, so that the main body 6 a side (left side in FIG. 1) is mainly heated more than the heat insulating cloth 51. Therefore, the opposite side (the right side in FIG. 1) is not easily heated. In particular, since the other end side of the heat insulating cloth 51 is configured to be in pressure contact with the insulating plate 12, as shown in FIG. 8, it is difficult to form a gap between the other end side of the heat insulating cloth 51 and the insulating plate 12, It is difficult for heat to leak from the main body 6a side. As a result, various problems caused by heat leakage (for example, damage to electronic components such as a not-shown posistor attached to the insulating plate 12 or energy loss caused by heat leakage) can be suppressed.
[0044]
Moreover, since the heat insulation cloth 51 is comprised with the heat insulation cloth by which the metal coating was given with respect to the cloth, it is easy to process etc. and the heat retention effect by a radiant heat increases. In addition, moderate bending can be expected, and a predetermined sealing property can be ensured without employing any special means.
[0045]
In addition, you may implement as follows, for example, without being limited to the content of description of embodiment mentioned above.
[0046]
(A) Although not specifically mentioned in the above embodiment, as shown in FIG. 9, at least the lead wire 43 in the contact portion with the insulating plate 12 on the other end side (right side in the drawing) of the heat insulating cloth 51. It is good also as forming the slit 53 in the corresponding site | part. With this configuration, the lead wire 43 enters the slit 53, and the contact area with the insulating plate 12 on the other end side of the heat insulating cloth 51 increases. Therefore, the gap is further narrowed. As a result, heat leakage can be further suppressed.
[0047]
(B) Also, as shown in FIG. 10 (a) or (b), at least a portion corresponding to the lead wire 43 in the contact portion with the insulating plate 12 on the other end side of the heat insulating cloth 51 has a fluffy member. 54 and 55 may be provided. With this configuration, the lead wire 43 enters between the fluffy members 54 and 55, and the contact area of the other end side (including the fluffy members 54 and 55) of the heat insulating cloth 51 to the insulating plate 12 is increased. The gap will be further narrowed. As a result, heat leakage can be further suppressed.
[0048]
(C) Further, as shown in FIG. 11, at least a contact portion of the heat insulating cloth 51 with the insulating plate on the other end side is made of a material that can be elastically compressed and deformed (for example, silicon rubber or other gel material). It may be. With such a configuration, even if the lead wire 43 hits, the contact portion is elastically compressed and deformed, so that the gap is further narrowed, and the sealability of the contact portion and its vicinity can be improved. .
[0049]
(D) In the above-described embodiment, one and two heat insulating cloths 51 are attached to the pair of spring holder supports 35, respectively. It may be one by one.
[0050]
(E) In the above embodiment, the heat insulating cloth 51 is used as the heat insulating material, but the heat insulating cloth 51 is not necessarily limited to a cloth shape, and is constituted by a flexible sheet member or plate member. May be.
[0051]
(F) As a means for attaching to the spring holder support 35, other means such as an adhesive and a bolt may be employed in addition to the rivet.
[0052]
(G) In the said embodiment, although it becomes the structure by which a hot air is blown out in the heating furnace 21, the structure which only heats with a heater, without sending a wind may be sufficient.
[0053]
(H) The number of elements 6 attached to the holder 7 and the number of holders 7 attached to the rotating body 8 are not limited to those of the above embodiment.
[Brief description of the drawings]
FIG. 1 is a schematic side view showing an aging holder and a heat insulating cloth in an embodiment.
FIG. 2 is a cross-sectional view showing an aging device.
FIG. 3 is a cross-sectional view showing an aging device.
FIG. 4 is a front sectional view showing a holder and the like.
FIG. 5 is a front sectional view showing a mounting state of the holder.
FIG. 6 is a side view showing a mounting state of the holder.
FIG. 7 is a diagram showing a positional relationship between a lead wire and a leaf spring related to an electrode plate.
FIG. 8 is a partial plan view for explaining a state of a gap on both sides of an insulating plate.
FIG. 9 is a partial plan view showing a heat insulating cloth and the like in another embodiment.
FIGS. 10A and 10B are partial side views showing a heat insulating cloth and the like according to another embodiment.
FIG. 11 is a partial cross-sectional view showing a heat insulating cloth or the like in another embodiment.
It is a front view which shows the attachment state of the conventional holder for aging.
FIG. 12 is a side view showing a mounting state and the like of a conventional holder.
FIG. 13 is a partial plan view for explaining a state of a gap on both sides of an insulating plate in a state where a conventional holder is attached.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Aging apparatus, 5 ... Rotating shaft, 6 ... (Electrolytic capacitor) element, 7 ... Holder, 8 ... Rotating body, 11 ... Mounting tool, 12 ... Insulating plate as plate-shaped body, 21 ... Heating furnace, 51 ... Insulating cloth as a heat insulating material, 53... Slit, 54, 55.

Claims (7)

A heating furnace for applying heat from the outer peripheral side toward the inside;
A long plate-like body configured to be able to be mounted by straddling the lead wires, and a plurality of electrolytic capacitor elements composed of a main body portion and a pair of lead wires extending from the main body portion, and both sides of the plate-like body A plurality of holders provided with clamping means capable of being clamped so as to come into contact with the lead wire from
In an aging apparatus for electrolytic capacitor elements, comprising: a rotational movement means for rotationally moving the holder in the heating furnace;
When a heat insulating material having flexibility is attached to the clamping means, and the clamping means is in contact with the lead wire, one end side of the heat insulating material overlaps with the heat insulating material of the adjacent holder, An aging device for an electrolytic capacitor, characterized in that the other end side of the heat insulating material is in contact with the plate-like body. A heating furnace for applying heat from the outer peripheral side toward the inside;
A rotating shaft rotatably supported in the heating furnace;
A pair of substantially disk-like or substantially wheel-like rotating bodies provided at a distance from each other with respect to the rotating shaft;
A long plate-like body configured to be able to be mounted by straddling the lead wires, and a plurality of electrolytic capacitor elements composed of a main body portion and a pair of lead wires extending from the main body portion, and both sides of the plate-like body Aging of an electrolytic capacitor element comprising clamping means that can be clamped so as to come into contact with the lead wire, and a plurality of holders that are attached to a substantially outer peripheral portion of the pair of rotating bodies at predetermined intervals so as to face each other. In the device
When a heat insulating material having flexibility is attached to the clamping means, and the clamping means is in contact with the lead wire, one end side of the heat insulating material overlaps with the heat insulating material of the adjacent holder, An aging device for an electrolytic capacitor, characterized in that the other end side of the heat insulating material is in contact with the plate-like body. The clamping means includes an elastic member that can contact the lead wire and can be electrically connected, and a support means that directly or indirectly supports the elastic member, and the heat insulating material has at least the other end side thereof. 3. The electrolytic capacitor element aging device according to claim 1, wherein the aging device is attached to the support means so as to extend beyond the elastic member. The aging device for an electrolytic capacitor element according to any one of claims 1 to 3, wherein the heat insulating material is constituted by a heat insulating cloth in which a metal coating is applied to the cloth. 5. The electrolytic capacitor element according to claim 1, wherein at least a portion of the heat insulating material in contact with the plate-like body on the other end side is made of an elastically compressible material. Aging equipment. The slit is formed in the site | part corresponding to the said lead wire at least in the site | part corresponding to the said plate-shaped body of the said other end side of the said heat insulating material. The aging apparatus of the electrolytic capacitor element of description. 7. A fluff-like member is provided at least in a portion corresponding to the lead wire in a portion of the heat insulating material that contacts the plate-like body on the other end side. An aging device for an electrolytic capacitor element according to claim 1.

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