JP4877110B2 - Capacitor lead terminal manufacturing method - Google Patents

Description

  The present invention relates to a capacitor lead terminal configured by arc welding a metal wire in which a metal plating layer mainly composed of tin is formed on an aluminum wire connected to a capacitor element.

  Conventionally, a lead terminal of an electronic component uses a copper-coated steel wire having a lead plating layer joined to an aluminum wire by arc welding. However, in copper-coated steel wires containing lead, lead is not only harmful to the human body, but also has a negative effect on the natural environment. In recent years, development of electronic components that do not use lead at all has been promoted from the viewpoint of environmental protection. ing. For example, like an aluminum electrolytic capacitor shown in Patent Document 1, a copper-coated steel wire plated with tin consisting of 100% tin is inserted into a recess provided at one end of an aluminum wire and joined by arc welding. In this aluminum electrolytic capacitor, an alloy layer of copper, tin, and aluminum formed by heating a copper-coated steel wire, a tin plating, and an aluminum wire is formed at the joint between the copper-coated steel wire and the aluminum wire. ing.

  However, in the aluminum electrolytic capacitor described in Patent Document 1, in the lead wire that does not use lead, the alloy layer generated at the connection portion (welded portion) between the aluminum wire and the tin-plated copper-coated steel wire is not used. In addition, a mixed layer of aluminum and tin is included, and the presence of this mixed layer may cause tin whiskers. This whisker may reach a length of 1 mm or more with respect to a diameter of 1 μm, and this whisker may short-circuit the electronic component of the capacitor.

  Therefore, as a result of intensive research to solve the above problems, the inventors of the present application, as shown in Patent Document 2, mechanically removed the metal plating layer of the metal wire, A lead terminal for a capacitor that does not contain lead can be manufactured and a whisker can be generated by bringing a non-contact portion into contact with an aluminum wire and welding by passing a welding current between the metal wire and the aluminum wire. Invented a capacitor lead terminal that can be prevented.

JP 2000-124073 (page 3, FIG. 1) Japanese Patent Application No. 2007-93957

  However, by removing the metal plating layer of the metal wire, since there is no tin in the welded portion, whisker generation is reduced, but the shape of the welded portion between the metal wire and the aluminum wire is not stable and melted. The weld is not formed so that the aluminum covers the metal wire, but a gap is formed between the metal wire and the aluminum wire, the contact resistance increases, and the mechanical strength of the weld decreases. In some cases, the reliability of the lead terminals could not be satisfied. When this phenomenon was analyzed, the surface of the metal wire was in a state of low wettability because the tin plating layer was removed, and a part of the aluminum wire melted during welding was along the surface of the metal wire. It was found that there was a gap between the molten aluminum and the metal wire.

  The present invention has been made paying attention to such problems, and in the method of manufacturing a lead terminal for a capacitor that does not contain lead, the occurrence of whiskers can be prevented and the welded portion can be formed in a stable shape. It aims at providing the manufacturing method of the lead terminal for capacitors.

In order to solve the above-mentioned problem, a method of manufacturing a capacitor lead terminal according to claim 1 of the present invention includes:
In the method of manufacturing a lead terminal for a capacitor, wherein a metal wire formed with a metal plating layer mainly composed of tin is brought into contact with an aluminum wire, and the metal wire and the aluminum wire are arc-welded.
A portion without a metal plating layer is provided at one end of the metal wire, one end of the metal wire and one end of the aluminum wire are brought into contact with each other, the arc welding is performed, and a welded portion between the metal wire and the aluminum wire is provided. It is characterized by being molded into a desired shape with a mold.
According to this feature, the welded portion of the metal wire and the aluminum wire formed by arc welding does not need to mix aluminum and tin, the occurrence of whiskers in the welded portion is suppressed, and the metal wire Although there is no metal plating layer on the surface of the weld, the wettability of the surface is reduced, but the desired weld shape can be stabilized by forming the weld between the metal wire and the aluminum wire with a mold. The mechanical strength of the welded portion of the lead terminal can be improved.
When forming a portion without a metal plating layer on a metal wire, the metal plating layer may not be formed in advance by masking or the like, or a metal plating layer is formed on the entire surface of the metal wire and mechanically removed. The metal plating layer may be removed by such means. Especially, the metal plating layer on the surface of the metal wire is surely removed by mechanical removal, so that the mixed layer of metal plating layer and aluminum is not formed in the welded part, and the generation of whiskers in the welded part is effective. Can be suppressed.

The method for manufacturing a capacitor lead terminal according to claim 2 of the present invention is as follows.
In the method of manufacturing a lead terminal for a capacitor, wherein a metal wire formed with a metal plating layer mainly composed of tin is brought into contact with an aluminum wire, and the metal wire and the aluminum wire are arc-welded.
A portion without the metal plating layer and the metal plating layer is continuously provided from one end of the metal wire, one end of the metal wire and one end of the aluminum wire are brought into contact with each other, the arc welding is performed, and the metal wire The welded portion with the aluminum wire is formed into a desired shape with a mold.
According to this feature, when the metal wire and the aluminum wire are brought into contact with each other and arc-welded, the contact resistance between the metal wire and the aluminum wire is brought into contact with the metal wire and the aluminum wire through the metal plating layer. Current can flow in a low state, so that poor welding is reduced, and the welding portion of the metal wire and aluminum wire formed by arc welding has a low mixing ratio of tin, and lead terminals Occurrence of whiskers in the welded portion is suppressed. And although there is almost no metal plating layer on the surface of the welded portion of the metal wire, the wettability of the surface is reduced, but the desired weld is achieved by forming the welded portion of the metal wire and the aluminum wire with a mold. The shape of the portion can be formed stably, and the mechanical strength of the welded portion of the lead terminal can be improved.

The method for producing a capacitor lead terminal according to claim 3 of the present invention is the method for producing a capacitor lead terminal according to claim 1 or 2,
The mold is provided on a chuck that holds the metal wire.
According to this feature, at the time of manufacturing the lead terminal, the metal wire holding work and the mold placing work can be performed at the same time, and it can also be used as a current-carrying tool during arc welding. It can be done promptly.

The method for manufacturing a capacitor lead terminal according to claim 4 of the present invention is the method for manufacturing a capacitor lead terminal according to claim 1,
The metal mold is disposed so as to cover a portion without the metal plating layer, and the metal plating layer is separated from a welded portion formed by the arc welding by the metal mold.
According to this feature, the tin of the metal plating layer is not mixed with the welded portion melted by arc welding, tin is not mixed with the welded portion, and the occurrence of whiskers in the welded portion at the lead terminal is suppressed.

The method for manufacturing a capacitor lead terminal according to claim 5 of the present invention is the method for manufacturing a capacitor lead terminal according to claim 2,
A metal plating layer provided at one end of the metal wire is covered with a welded portion formed by the arc welding.
According to this feature, the metal plating layer provided at one end of the metal wire containing tin is buried in the welded portion, so that the tin does not need to be mixed in the vicinity of the surface of the welded portion. Occurrence of whiskers in the weld is suppressed.

  BEST MODE FOR CARRYING OUT THE INVENTION The best mode for carrying out a method for manufacturing a capacitor lead terminal according to the present invention will be described below based on examples.

  An embodiment of the present invention will be described with reference to the drawings. First, FIG. 1A is a schematic cross-sectional view showing a step of removing a tin plating layer formed on the surface of a metal wire in Embodiment 1, and FIG. FIG. 2B is a schematic cross-sectional view showing the metal wire from which the tin plating layer has been removed, and FIG. 2A is a schematic cross-sectional view showing a state before the metal wire and the aluminum wire are welded. ) Is a schematic cross-sectional view showing a state during welding of the metal wire and the aluminum wire, and FIG. 2C is a schematic cross-sectional view showing a state after welding of the metal wire and the aluminum wire.

  The capacitor according to the present embodiment accommodates a capacitor element in which a plurality of electrode foils formed of aluminum are wound or laminated via a separator in a low-cylindrical outer case, and has an opening formed in the outer case. While sealing with the sealing body, the lead terminal led from the capacitor element is penetrated through the sealing body and led out to the outside.

  The lead terminal is composed of an aluminum wire 5 connected to the capacitor element and a metal wire 1 (CP wire) having the mild steel wire 4 as a core (see FIG. 2C). As shown in FIG. 1 (a), a metal wire 1 includes a mild steel wire 4 as a core material and a copper cover layer 3 formed by thickly plating copper as a metal material on the outer periphery thereof, and tin as a metal material on the outer periphery thereof. A tin plating layer 2 made of 100% is formed. The lead wire is not used at all for the material constituting the metal wire 1, and lead is not used at all for the material constituting the aluminum wire 5 or the capacitor element. Is a lead-free electronic component that does not contain lead and does not adversely affect the natural environment.

  As shown in FIG. 1A, the metal wire 1 is formed by cutting a rod-shaped body into a plurality of pieces. Here, the tin plating layer 2 on the surface of the metal wire 1 is removed by a mechanical means such as a cutter 8 at a portion related to the tip (one end) of the metal wire 1, and a plurality of tin plating layers are formed on the rod-shaped body. A missing portion 9 is formed. By cutting the rod-like body at the end of the portion 9 without the tin plating layer (see the one-dot chain line in FIG. 1B), the metal wire 1 in which the portion 9 without the tin plating layer is formed at the tip (one end). Is formed. In Examples 2 and 3, which will be described later, the cut portion of the rod-like body is not the end portion of the portion 9 without the tin plating layer, but is cut on the adjacent metal plating layer 2 to the tip portion (one end). The metal wire 1 leaving the tin plating layer is formed. In the present embodiment, the cutter 8 is pushed from the tin plating layer 2 to a depth reaching a part of the copper cover layer 3, and the cutter 8 is moved in the direction of the arrow, as shown in FIG. 2 and a part of the copper cover layer 3 are removed to form a portion 9 having no tin plating layer. Here, the copper covering layer 3 is also removed and the mild steel wire 4 can be exposed on the surface. However, by leaving a part of the copper covering wire 3, arc welding with the aluminum wire 5 described later is performed with high accuracy. be able to. In addition, the tin plating layer 2 can be removed by means such as polishing or grinding. It is preferable to remove the tin plating layer 2 so that the range of the portion 9 without the tin plating layer is not included in the welded portion 10 with the aluminum wire 5 described later. The location where whiskers occur in the capacitor lead terminal is a welded portion 10 (see FIG. 2C) between the metal wire 1 and the aluminum wire 5, which is a mixture of tin and aluminum used as metal plating during welding. It is considered that whiskers are generated by the stress applied to tin. For this reason, it is necessary to remove the tin plating layer 2 at the tip of the metal wire 1 with certainty, and therefore, mechanical means are used. Further, in addition to the tin plating layer 2, a part of the copper covering layer 3 is used. It is more effective to remove it.

  Next, a method for connecting the aluminum wire 5 and the metal wire 1 when the metal wire 1 is manufactured will be described. First, as shown in FIG. 2 (a), the aluminum wire 5 has a round bar portion 6 having a substantially cylindrical shape formed at one end thereof, and the round bar portion 6 is connected to the metal wire 1 by the manufacturing method of the present invention. Is done. Further, a flat portion 7 having a substantially flat shape is formed at the other end of the aluminum wire 5, and the flat portion 7 is connected to the electrode foil of the capacitor element. The vicinity of the end of the aluminum wire 5 is fixed by the fixed chuck 13, and the vicinity of the end of the metal wire 1 is held by the movable chuck 14, and the tip portion from which the tin plating layer 2 has been removed is disposed opposite to the fixed interval. . In this case, an arc welding apparatus is connected to the metal wire 1 and the aluminum wire 5. The fixed chuck 13 and the movable chuck 14 can also be used as a power tool for an arc welding apparatus.

  As shown in FIG. 2B, the fixed chuck 13 and the movable chuck 14 that are configured in half are held so as to sandwich the aluminum wire 5 and the metal wire 1 from above and below, respectively. The movable chuck 14 is formed with a mold part 14a having a substantially hemispherical shape. The movable chuck 14 is configured to hold the portion 9 of the metal wire 1 without the tin plating layer so that the mold portion 14a covers the periphery of the portion 9 without the tin plating layer. Note that the portion 9 having no tin plating layer and the tin plating layer 2 are separated from each other by the mold portion 14 a of the movable chuck 14.

  Next, the metal wire 1 is moved in the direction of the aluminum wire 5 by the movable chuck 14, and the tip portion of the metal wire 1 is caused to collide with a predetermined position on the end surface of the aluminum wire 5 to be brought into contact with the end surface. In this state, when the welding apparatus is operated, a welding current flows between the metal wire 1 and the aluminum wire 5, and the contact point between the metal wire 1 and the aluminum wire 5, that is, the tip of the metal wire 1 and the aluminum wire. The arc welding current starts to flow between the end face of 5.

  When the leading end of the metal wire 1 is moved away from the end surface of the aluminum wire 5 and the interval is set between them from the start of energization of the welding current, an arc is formed between the leading end portion of the metal wire 1 and the end surface of the aluminum wire 5 And both the opposing metal wire 1 and aluminum wire 5 are partially melted.

  In this state, when the metal wire 1 is moved to the end face side of the aluminum wire 5 to be brought into contact with and pressed further, fusion between the molten metals occurs, and the metal wire 1 and the end face of the aluminum wire 5 are welded. At this time, since the mold part 14a of the movable chuck 14 moves to the end face side of the aluminum wire 5, the molten metal is molded along the shape in the mold part 14a, so that the hemispherical weld 10 is formed. As shown in FIG. 2C, a lead terminal in which the metal wire 1 and the aluminum wire 5 are integrated is formed. In this case, the welded portion 10 forms an alloy layer by fusing the metal constituting the metal wire 1 and the metal constituting the aluminum wire 5. Since the tin plating layer 2 formed on the surface of the metal wire 1 is previously removed from the welded portion 10, the tin plated layer 2 is not mixed in the welded portion 10. Therefore, the generation of whiskers due to the mixed layer of the tin plating layer 2 and aluminum is suppressed.

  As described above, in the method of manufacturing a capacitor lead terminal according to the present embodiment, the metal wire 1 and the aluminum wire formed by arc welding are provided with the portion 9 without the tin plating layer from which the tin plating layer 2 is removed at one end of the metal wire 1. In the welded portion 10 with 5, aluminum 5 and tin are not mixed, and the occurrence of whiskers in the welded portion 10 is suppressed. Further, one end of the metal wire 1 and one end of the aluminum wire 5 are brought into contact with each other, arc welding is performed, and a welded portion 10 between the metal wire 1 and the aluminum wire 5 is formed by a mold portion 14a. The shape of the welded portion can be stably formed, and the mechanical strength of the welded portion 10 of the lead terminal can be improved.

  In particular, since the tin plating layer 2 on the surface of the metal wire 1 is surely removed by mechanical removal, a mixed layer of the tin plating layer 2 and the aluminum 5 is not formed in the welding portion 10, and the welding portion The generation of 10 whiskers can be effectively suppressed.

  In addition, since the mold part 14a is provided on the movable chuck 14 that holds the metal wire 1, the metal wire 1 holding work and the mold part 14a placement work can be performed at the same time when the lead terminal is manufactured. In addition, it can be used as a power tool during arc welding, and the arc welding operation can be performed quickly.

  Further, the mold part 14a is disposed so as to cover the portion 9 without the tin plating layer, and the welding part 10 formed by arc welding and the tin plating layer 2 are separated by the mold part 14a, so that the tin The tin of the plating layer 2 is not mixed with the welded portion 10 melted by arc welding, tin is not mixed with the welded portion 10, and the occurrence of whiskers in the welded portion 10 at the lead terminal is suppressed.

  Next, a method for manufacturing a capacitor lead terminal according to Embodiment 2 will be described with reference to FIG. It should be noted that the same components as those shown in the above-described embodiment are denoted by the same reference numerals and redundant description is omitted. 3A is a schematic cross-sectional view showing a state before welding of a metal wire and an aluminum wire in Example 2, and FIG. 3B is a schematic cross-section showing a state during welding of the metal wire and the aluminum wire. FIG. 3C is a schematic cross-sectional view showing a state after welding of a metal wire and an aluminum wire.

  The tip portion (one end) of the metal wire 1 is a portion 9 without a plurality of tin plating layers on the rod-shaped body constituting the metal wire 1 by mechanical means such as a cutter 8 (see FIG. 1) as in the first embodiment. Is cut on the metal plating layer 2 adjacent to the portion 9 without the tin plating layer, leaving the tin plating portion 2a on the outer peripheral surface in the vicinity of the tip of the metal wire 1, and the portion 9 without the tin plating layer The metal wire 1 provided with is formed. The aluminum wire 5 is fixed by the fixed chuck 13, the metal wire 1 is held by the movable chuck 14, and the tip portions where the tin-plated portions 2a are partially left are arranged to face each other at a constant interval. In this case, an arc welding apparatus is connected to the metal wire 1 and the aluminum wire 5.

  As shown in FIG. 3B, the fixed chuck 13 and the movable chuck 14 are held so as to sandwich the aluminum wire 5 and the metal wire 1 from above and below, respectively. The movable chuck 14 is formed with a mold part 14a having a substantially hemispherical shape. The movable chuck 14 is configured to hold the portion 9 of the metal wire 1 without the tin plating layer so that the mold portion 14a covers the periphery of the portion 9 without the tin plating layer. Note that the portion 9 having no tin plating layer and the tin plating layer 2 are separated from each other by the mold portion 14 a of the movable chuck 14.

  Next, the metal wire 1 is moved in the direction of the aluminum wire 5 by the movable chuck, and the tip portion of the metal wire 1 is caused to collide with a predetermined position on the end surface of the aluminum wire 5 so as to contact the end surface. Here, the tin plating portion 2a left on the outer peripheral surface of the metal wire 1 is brought into contact with the aluminum wire. When the welding apparatus is operated in this state, a welding current is generated between the metal wire 1 and the aluminum wire 5. In particular, the metal wire 1 and the aluminum wire 5 become conductive through the tin-plated portion 2a left on the outer peripheral surface, and the arc welding current starts to flow. Thereafter, when the tip of the metal wire 1 is separated from the end face of the aluminum wire 5 and a distance is set between them, an arc is generated between the tip of the metal wire 1 and the end face of the aluminum wire 5, and the opposing metal wire 1 Both the aluminum wire 5 and the aluminum wire 5 are partially melted.

  In this state, when the metal wire 1 is moved to the end face side of the aluminum wire 5 to be brought into contact with and pressed further, fusion between the molten metals occurs, and the metal wire 1 and the end face of the aluminum wire 5 are welded. At this time, since the mold part 14a of the movable chuck 14 moves to the end face side of the aluminum wire 5, the molten metal is molded along the shape in the mold part 14a, so that the hemispherical weld 10 is formed. As shown in FIG. 3C, a lead terminal in which the metal wire 1 and the aluminum wire 5 are integrated is formed. As in the first embodiment, since the tin-plated layer 2 is removed in advance in the welded portion 10 except for portions left on the outer peripheral surface of the metal wire 1, the welded portion 10 includes Almost no tin plating layer 2 is mixed. Moreover, since the tin-plated portion 2a partially left on the outer peripheral surface of the metal wire 1 is buried in the aluminum wire 5 at the time of welding, there is no tin-plated layer 2 near the surface of the welded portion. The generation of whiskers due to the mixed layer of the tin plating layer 2 and aluminum is suppressed.

  Next, a method for manufacturing a capacitor lead terminal according to Embodiment 3 will be described with reference to FIG. It should be noted that the same components as those shown in the above-described embodiment are denoted by the same reference numerals and redundant description is omitted. FIG. 4A is a schematic cross-sectional view showing a state before welding of a metal wire and an aluminum wire in Example 3, and FIG. 4B is a schematic cross-section showing a state during welding of the metal wire and the aluminum wire. FIG. 4C is a schematic cross-sectional view showing a state after welding of the metal wire and the aluminum wire.

  As shown in FIG. 4A, the metal wire 1 has a tapered surface 11 formed toward the tip (one end). As in the first embodiment, this tapered surface 11 is formed by forming a portion 9 without a plurality of tin plating layers on the rod-shaped body constituting the metal wire 1 by mechanical means such as a cutter 8 (see FIG. 1). By cutting on the metal plating layer 2 adjacent to the portion 9 having no plating layer, the metal wire 1 is formed with the tin plating portion 2a left on the outer peripheral surface near the tip of the metal wire 1, and then the metal wire 1 The tin-plated portion 2a and the portion 9 without the tin-plated layer are formed by compressing with a mold or the like, and a tin-plated portion 2a composed of the remaining metal-plated layer is formed at the tip of the tapered surface 11. . On the other hand, the aluminum wire 5 is provided with a concave portion 12 having a storage space that fits the tapered surface 11 of the metal wire 1 at the end surface on the contact side with the metal wire 1. The aluminum wire 5 is fixed by the fixed chuck 13, the metal wire 1 is held by the movable chuck 14, and the tip portions where the tin-plated portions 2a are partially left are arranged to face each other at a constant interval. In this case, an arc welding apparatus is connected to the metal wire 1 and the aluminum wire 5.

  As shown in FIG. 4B, the fixed chuck 13 and the movable chuck 14 are held so as to sandwich the aluminum wire 5 and the metal wire 1 from above and below, respectively. The movable chuck 14 is formed with a mold part 14a having a substantially hemispherical shape. The movable chuck 14 is configured to hold the portion 9 of the metal wire 1 without the tin plating layer so that the mold portion 14a covers the periphery of the portion 9 without the tin plating layer. Note that the portion 9 having no tin plating layer and the tin plating layer 2 are separated from each other by the mold portion 14 a of the movable chuck 14.

  Next, the metal wire 1 is moved in the direction of the aluminum wire 5 by the movable chuck, and the tip end portion of the taper surface 11 is made to collide with the aluminum wire 5. At this time, the metal wire 1 is guided to a predetermined position by the concave portion 12 of the aluminum wire 5. As a result, the metal wire 1 and the aluminum wire 5 come into contact with each other. Here, the tin plating portion 2a left on the outer peripheral surface of the metal wire 1 is brought into contact with the aluminum wire 5, and in this state, when the welding apparatus is operated, a welding current is generated between the metal wire 1 and the aluminum wire 5. In particular, the metal wire 1 and the aluminum wire 5 become conductive through the tin-plated portion 2a left on the outer peripheral surface, and an arc welding current starts to flow. Thereafter, when the tip of the metal wire 1 is separated from the end face of the aluminum wire 5 and a distance is set between them, an arc is generated between the tip of the metal wire 1 and the end face of the aluminum wire 5, and the opposing metal wire 1 Both the aluminum wire 5 and the aluminum wire 5 are partially melted.

  In this state, when the metal wire 1 is moved to the end face side of the aluminum wire 5 to be brought into contact with and pressed further, fusion between the molten metals occurs, and the metal wire 1 and the end face of the aluminum wire 5 are welded. At this time, since the mold part 14a of the movable chuck 14 moves to the end face side of the aluminum wire 5, the molten metal is molded along the shape in the mold part 14a, so that the hemispherical weld 10 is formed. As shown in FIG. 4C, a lead terminal in which the metal wire 1 and the aluminum wire 5 are integrated is formed. As in the second embodiment, since the tin-plated layer 2 is removed in advance in the welded portion 10 except for portions left partially on the outer peripheral surface of the metal wire 1, Almost no tin plating layer 2 is mixed. Moreover, since the tin-plated portion 2a partially left at the tip of the metal wire 1 is buried in the aluminum wire 5 during welding, there is no tin-plated layer 2 in the vicinity of the surface of the welded portion. The generation of whiskers due to the mixed layer of the tin plating layer 2 and aluminum is suppressed.

  As mentioned above, in the manufacturing method of the lead terminal for capacitors in Examples 2 and 3, the tin plating layer 2 and the portion 9 without the tin plating layer are continuously provided from one end of the metal wire 1, and one end of the metal wire 1 and the aluminum wire 5 are provided. The metal wire 1 and the aluminum wire 5 are formed by forming a welded portion 10 of the metal wire 1 and the aluminum wire 5 into a desired shape with a mold 14a. The current can be passed in a state where the contact resistance is low, so that welding defects are reduced. In addition, the welding part 10 of the metal wire 1 and the aluminum wire 5 formed by arc welding has a low mixing ratio of tin, and the occurrence of whiskers of the welding part 10 at the lead terminal is suppressed.

  Moreover, the tin-plated part 2a is covered with the welded part 10 formed by arc welding, so that the tin-plated part 2a containing tin is buried in the welded part 10, and in the vicinity of the surface of the welded part 10, Will not be mixed, and the occurrence of whiskers in the welded portion 10 at the lead terminal is suppressed.

  Further, as the tin plating portion 2a provided at the tip end portion of the metal wire 1, the tin plating portion 2a is provided at the tip end portion of the metal wire 1 by, for example, subsequently performing tin plating on the portion 2a without the tin plating layer. May be.

  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 each embodiment, the tin plating layer 2 is formed on the entire surface of the metal wire 1, and the tin plating layer 2 is removed by means such as mechanical removal to form the portion 9 without the tin plating layer. Alternatively, the tin plating layer 2 may be removed by masking or the like to form a portion 9 having no tin plating layer on the metal wire 1.

  In each embodiment, the tin plating layer 2 made of 100% tin is formed on the outer periphery of the metal wire 1, but it is not always necessary to form the plating layer with 100% metal material. The plating layer may be formed of an alloy added with a metal such as.

  Moreover, in each Example, although the mild steel wire is used as a core material of the metal wire 1, a copper wire can be used besides this. In this case, the tin plating layer 2 can be directly formed on the metal wire 1 made of the copper wire (core material).

  In each embodiment, the aluminum wire 5 is held by the fixed chuck and the metal wire 1 is held by the movable chuck. However, the present invention is not limited to this, and the metal wire 1 is held by the fixed chuck. It is also possible to hold the aluminum wire 5 and move the aluminum wire 5 held by the movable chuck to the metal wire 1 for welding.

  In each embodiment, as an arc welding method, a welding current is passed in a state where the metal wire 1 is in contact with the aluminum wire 5 (or the aluminum wire 5 is in contact with the metal wire 1), and then the tip of the metal wire 1 is used. Is separated from the end face of the aluminum wire 5, an arc is generated between them, and both the metal wire 1 and the aluminum wire 5 facing each other are partially melted, and then the metal wire 1 is moved to the end face side of the aluminum wire 5 (or The aluminum wire 5 is moved to the end face side of the metal wire 1 and brought into contact therewith, and further pressed to cause fusion between the molten metals, and the metal wire 1 and the aluminum wire 5 are welded. Not limited to this, a welding current is passed in a state in which the metal wire 1 is in contact with the aluminum wire 5 (or the aluminum wire 5 is in contact with the metal wire 1), and an arc is generated in this state to partially connect the metal wire 1 and the aluminum wire 5 Melting So, by pushing further the metal wire 1 (or the aluminum wire 5), causing fusion between the molten metal may be welded metal wire 1 and the aluminum wire 5.

  Moreover, in each Example, although the metal mold | die part 14a of the movable chuck | zipper 14 has arrange | positioned so that the circumference | surroundings of the part 9 without the tin plating layer of the metal wire 5 may be covered, not only this but a movable chuck is metal wire 5 You may arrange | position on the tin plating layer 2 of this.

(A) is a schematic sectional drawing which shows the removal process of the tin plating layer formed in the surface of the metal wire in Example 1, (b) is a schematic sectional drawing which shows the metal wire from which the tin plating layer was removed. It is. (A) is a schematic sectional drawing which shows the state before welding of a metal wire and an aluminum wire, (b) is a schematic sectional drawing which shows the state at the time of welding of a metal wire and an aluminum wire, (c) is It is a schematic sectional drawing which shows the state after welding of a metal wire and an aluminum wire. (A) is a schematic sectional drawing which shows the state before welding of the metal wire and aluminum wire in Example 2, (b) is a schematic sectional drawing which shows the state at the time of welding of a metal wire and an aluminum wire, (C) is a schematic sectional drawing which shows the state after the welding of a metal wire and an aluminum wire. (A) is a schematic sectional drawing which shows the state before welding of the metal wire and aluminum wire in Example 3, (b) is a schematic sectional drawing which shows the state at the time of welding of a metal wire and an aluminum wire, (C) is a schematic sectional drawing which shows the state after the welding of a metal wire and an aluminum wire.

Explanation of symbols

1 Metal wire 2 Tin plating layer (metal plating layer)
2a Tin plating part (metal plating layer)
3 Copper coating layer 4 Steel wire 5 Aluminum wire 6 Round bar portion 7 Flat portion 8 Cutter 9 Portion without tin plating layer (portion without metal plating layer)
DESCRIPTION OF SYMBOLS 10 Welding part 11 Tapered surface 12 Recessed part 13 Fixed chuck 14 Movable chuck 14a Mold part

Claims (5)

In the method of manufacturing a lead terminal for a capacitor, wherein a metal wire formed with a metal plating layer mainly composed of tin is brought into contact with an aluminum wire, and the metal wire and the aluminum wire are arc-welded.
A portion without a metal plating layer is provided at one end of the metal wire, one end of the metal wire and one end of the aluminum wire are brought into contact with each other, the arc welding is performed, and a welded portion between the metal wire and the aluminum wire is provided. A method of manufacturing a lead terminal for a capacitor, which is formed into a desired shape by a mold. In the method of manufacturing a lead terminal for a capacitor, wherein a metal wire formed with a metal plating layer mainly composed of tin is brought into contact with an aluminum wire, and the metal wire and the aluminum wire are arc-welded.
A portion without the metal plating layer and the metal plating layer is continuously provided from one end of the metal wire, one end of the metal wire and one end of the aluminum wire are brought into contact with each other, the arc welding is performed, and the metal wire A method of manufacturing a lead terminal for a capacitor, wherein a welded portion with an aluminum wire is formed into a desired shape by a mold.   3. The method of manufacturing a capacitor lead terminal according to claim 1, wherein the mold is provided on a chuck for holding the metal wire.   The metal mold is disposed so as to cover a portion without the metal plating layer, and the metal plating layer is separated from a welded portion formed by the arc welding by the metal mold. The manufacturing method of the lead terminal for capacitors as described.   3. The method of manufacturing a capacitor lead terminal according to claim 2, wherein a metal plating layer provided at one end of the metal wire is covered with a welded portion formed by the arc welding.

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