JPH0217620A - Solder part clad wire - Google Patents

Abstract

PURPOSE:To obtain a clad were with improved wetting properties by cutting a long conductive metal wire into several pieces and making an area without solder flat after adhering solder to the surface of outer periphery of the long conductive metal wire in a certain gap and turning it into one piece when producing a metal wire material for lead terminals of each electronic component. CONSTITUTION:A long conductive metal wire 10 is allowed to pass between a backing roll 20 and a transfer roll 21 and a solder paste 11 is adhered to the surface of the metal wire 10 while it exists between these rolls. For adhering, a paste 11 is applied to a stainless roll 23 with recesses at certain gap from a paste pot 22 with a solder and a binder or a flux, the extra paste 11 is eliminated by a doctor blade 24, and the paste 11 is transferred to the roll 21. After that, heat treating is performed to make the metal wire 10 and solder into a solid piece, it is cut individually, and the edge part where no solder is adhered is flattened for obtaining a clad wire.

Description

[Detailed Description of the Invention] Field of Application The present invention relates to a metal wire material for lead terminals of various electronic components. This invention relates to a solder cladding wire with excellent processing and manufacturability.

Background Art A wide variety of glued terminals have been developed for energizing and signal lines of various electronic components. For example, the electric double layer capacitor shown in Fig. 5 usually has a disc-shaped main body (1 ), a pair of plate-shaped lead terminals (2X2
) is fixed.

Each lead terminal (2x2) has a connecting part (2a) fixed to the main body (1), and a wiring part formed on the board by being inserted into a through hole provided in an electric circuit board (not shown) and soldered. and a solder clad part (2b) that is electrically connected at.

These lead terminals (2) are often made of 5US304 stainless steel because of the need to prevent corrosion and electrolytic corrosion, and are usually made by Ni plating and then solder plating on both sides of the stainless steel plate. It was manufactured by punching out a so-called solder clad plate into a predetermined shape using a die as shown in FIG.

Problems with the Prior Art As mentioned above, lead terminals for various electronic components, including the lead terminals used in the electric double layer capacitor shown in Figure 5,
Most of them are inserted into through holes or the like provided on the substrate, and are electrically connected to wiring portions formed on the substrate by soldering.

Therefore, the solder wettability of the soldering part of the lead terminal is very important, and depending on the application, a wettability of 95% or more is required.

However, in a conventional lead terminal manufactured by punching out a solder clad plate with a metal mold, the solder clad portion (2) formed at the tip of the lead terminal (2) as shown in FIG.
In b), solder exists only on both sides of the stainless steel plate, and no solder exists on the side end surface (cut surface X2c).

This side end surface where no solder is present is not wetted by the solder during soldering, so there is a problem that the above-mentioned wettability of 95% or more of the wetted area cannot be satisfied.

OBJECTS OF THE INVENTION The object of the present invention is to provide a lead terminal material that solves the above-mentioned problems and allows lead terminals with significantly improved solder wettability to be efficiently manufactured on an industrial scale.

Summary of the Invention The present inventor has changed the technical concept of using conventional plate material as a material for lead terminals, and has devised a method for efficiently manufacturing required lead terminals by using wire rods to form cladding materials at predetermined intervals. I discovered that it is possible to do this.

That is, the present invention is a solder partial clad wire characterized in that solder is integrated all around the outer peripheral surface of the conductive metal wire at predetermined intervals in the axial direction of the conductive metal wire.

Structure of the Invention To explain an example of the solder part clad wire according to the present invention, as shown in FIGS. 1a and 1b, a conductive metal wire (
10), the solder (11) is wrapped around the entire outer periphery of the wire rod over the required length at regular intervals, as shown in Figure C (the wire thickness part and the solder part have the required ratio). After cutting the lead material (12), the wire portion can be flattened with a press and processed into a lead terminal (13) having a connecting portion (14) to an electronic component, for example, as shown in Figure d.

In this invention, the conductive metal wire is not only a normal cylindrical wire as shown in FIG. 1a, but also a prismatic wire of various shapes, or
It can be selected as appropriate depending on the purpose, wire size, etc., such as one whose parts other than the solder cladding part have been processed flat in advance.

Furthermore, in the case of solder that is clad around the entire circumference of a wire at predetermined intervals, the base metal part of the wire and the solder clad part are each provided with an axial length depending on the application, etc., but the terminal material after cutting is arranged in a fixed direction. In addition to providing a pattern like this (see Figure 1), it is also possible to provide a pattern with a predetermined interval so that the solder clad length is the desired length, such as cutting the solder clad part at the center to form two terminals. can.

In addition, the conductive metal wire may be appropriately selected in terms of corrosion resistance, strength, bendability, drawability, electrical conductivity, and heat conductivity.
Fe-Ni alloy, stainless steel, Ni, Cu, Cu
-Ni alloy is preferred, and in consideration of prevention of corrosion, electrolytic corrosion, etc. and integration with solder, it is desirable to apply Ni plating to the outer peripheral surface.

Furthermore, the stainless steel wire is preferably plated with Ni or Cu to improve solderability, and from the viewpoint of workability, Fe wire, Ni-Fe wire, etc.
Lines etc. can be selected as appropriate.

As a method for providing the above-mentioned conductive metal wire with a clad portion in which solder is wound around the entire outer periphery of the wire at predetermined intervals, the following various methods can be appropriately employed.

Manufacturing method (2) For example, as shown in FIG. 2, a conductive metal wire (10) is fed between a receiving roll (20) and a transfer roll (21).

At this time, from a paste pot (22) containing solder and binder or flux, it is applied to a stainless steel roll (23) having recesses of the desired shape at regular intervals,
Excess solder paste is removed with a doctor blade (24), and the solder paste in the recesses is transferred onto a transfer roll (2υ).

The transfer roll (21) made of silicone rubber is dented by the contact of the conductive metal wire (1o) on the roll (20) and contacts the upper half of the wire, so that the transferred solder paste is transferred. can be deposited on the conductive metal wire (10) at regular intervals.

After that, in order to firmly integrate the metal wire and the solder, a fusing process is performed to heat it above the melting point of the solder (usually 200°C to 240"C), but if flux is mixed into the solder paste, You can just heat it as is. If you do not want to mix flux, spray the required flux, apply it by dipping, etc., then heat treat it.
After cooling, excess flux is removed using an organic solvent or hot water.

Further, as the flux material, a known material such as zinc chloride flux is used, but it is preferable to select it in consideration of the composition ratio of the solder, ease of handling, etc.

In this fusing process, the solder paste applied to the upper half of the metal wire (10) at predetermined intervals is melted and wound around the entire outer periphery of the corresponding portion of the wire.

Manufacturing method■ As shown in Figure 3, an elastic material such as silicone rubber (
A predetermined amount of paste solder (32) is placed on the rotating roll (30) to which the metal wire (31) is attached, and as it rotates in the direction of the arrow in the figure, the metal wire ( 10) is pressed while being rotated in the direction of the arrow in the figure, thereby depositing the paste solder (32) on the rotating roll (30) in the circumferential direction of the outer peripheral surface of the conductive metal wire (10). I can do it.

In this method, by arranging a plurality of rotating rolls (30) at predetermined intervals in the axial direction of the metal wire (10), solder can be efficiently applied partially to predetermined positions of the metal wire (10). be able to.

In addition, in order to firmly integrate the metal wire and solder,
Perform the fusing treatment described above.

Manufacturing method ■ As shown in Figure 4a, paste solder (41) is applied to the opposing parts of a pair of hollow stamps (40 x 40) made of an elastic material such as silicone rubber, and a metal wire (- 10) and the hollow member (40X
By press-fitting air, gel, etc. into the hollow member (40) (40) at a predetermined pressure and pressing it, the hollow member (40) (40
) on the metal wire (10
) can be applied in the circumferential direction of the outer peripheral surface.

Further, a plurality of hollow stamps (40) are arranged radially on a rotating shaft parallel to the metal wire (10), and the metal wire (10)
While moving the paste solder intermittently in the axial direction,
41) By rotating the coated hollow stamp (40) and repeatedly pressing the metal wire (10) efficiently,
The solder can be partially applied at predetermined positions.

Furthermore, in order to firmly integrate the metal wire and the solder, the above-described fusing treatment is performed.

Note that stamps of various shapes can be used depending on the shape of the metal wire, etc., and the pressing method can be selected as appropriate.

Manufacturing method■ Although not shown, a straight slit nozzle that can discharge and drop the required amount of paste solder onto the metal wire, or a straight slit or curved slit nozzle that can directly discharge the solder onto the metal wire is provided, and the metal wire is continuously axially disposed. While moving in the direction, paste solder is intermittently discharged and deposited.
Furthermore, the solder partially clad metal wire according to the present invention can be obtained by fusing treatment.

Manufacturing method■ After applying solder plating to the entire conductive metal wire, a masking material such as acid-resistant ink is printed using printing technology at regular intervals in the axial direction of the wire and on the entire outer circumferential surface, and the entire wire is soldered. The partially soldered clad wire according to the present invention can be obtained by immersing the wire in an etching solution to remove the solder in the areas where the masking material is not applied, and further immersing the wire in an organic solvent bath to remove the masking material. Through the various manufacturing methods described above, solder partially clad wires can be provided with high productivity on an industrial scale.

Example 42 Outer diameter 1 made of Ni-Fe alloy. Using axial conductive metal wires, paste solder was applied 20 m in the axial direction of each of the metal wires by the method explained in FIG. 3 above.
m spacing, and a width of 1 in the circumferential direction of the outer peripheral surface of the metal wire.
It adhered to the shaft plate (see Figure 1).

After applying zinc chloride flux on the adhered paste solder, it was heated at 220°C to perform fusing treatment, and then washed with hot water at 80°C to remove excess flux, and a 10 pm thick sheet was applied. A solder cladding portion was formed.

After obtaining a solder partially clad wire according to the present invention by this manufacturing method, it was cut at a predetermined position and processed into a short metal wire whose blade end was not clad with solder.

Further, the portions not clad with the solder were flattened by pressing to form connection portions to the electronic component bodies to obtain lead terminals.

As shown in FIG. 1d, the lead terminal formed using the solder clad wire of the present invention has excellent solder wettability because solder is present all over the outer periphery of the tip that is inserted into the board and soldered. It was possible to achieve solder wettability with a wetted area of 95% or more, which is required in the field of electronic components.

[Brief explanation of the drawing]

FIG. 1 is a perspective explanatory view illustrating an embodiment of the present invention. FIGS. 2 and 3 are perspective explanatory views of a metal wire and a roll showing the manufacturing method of the present invention. FIG. 4 is a longitudinal cross-sectional view of a metal wire and a stamp showing the manufacturing method of the present invention. FIG. 5 is a perspective view of an electric double layer capacitor. DESCRIPTION OF SYMBOLS 10... Conductive metal wire, 11... Solder, 12 Lead material, 13... Lead terminal, 14... Connection part, 2
0...The receiver is a roll, 21...Transfer roll, 22...
・Paste pot, 23...Stainless steel roll, 2
4...Doctor blade, 30...Rotating roll, 3
1... Elastic body, 32.41... Paste solder,
40...Hollow stamp.

Claims (1)

[Scope of Claims] 1. A solder partial clad wire, characterized in that solder is integrated all around the outer peripheral surface of the conductive metal wire at predetermined intervals in the axial direction of the conductive metal wire.