JP2611716B2 - Manufacturing method of composite lead frame - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a composite lead frame formed by connecting an FPC or TAB tape and a lead frame. And a production method that can be performed with high productivity.

[0002]

2. Description of the Related Art FIG. 1 is a plan view showing the shape of a composite lead frame 100. FIG. The composite lead frame 100 includes an FPC or TAB tape 20 having an LSI mounting portion 1 and a copper foil pattern 4 as shown in FIG.
The inner lead 5 is held by the outer frame 9 and the tie bars 10 and 6
Frame 50 having metal and cushion leads 7 and 8
Are joined at the joint 3. Therefore, a particular problem in the manufacturing method of the composite lead frame 100 is that FP
This is a method of joining the C or TAB tape 20 and the lead frame 50.

Conventionally, as a method of joining an FPC or TAB tape to a lead frame, a heating joining method using a joining tool to which TAB outer lead bonding is applied is used. This method uses FPC or TAB
This is a method in which a tape and a lead frame are aligned, a portion to be joined is overlapped, and a joining tool processed to the size of the portion to be joined is pressed against a joining portion to perform heating joining.

[0004] The joint 3 shown in FIG.
1.5 mm wide, and at this joint 3, FPC or T
The AB copper foil pattern 4 and the inner lead 5 of the lead frame 50 are overlapped and connected. The shape of the conventional welding tool is such that the portion that comes into contact with the welding portion 3 is the width of the welding portion 3 and the planar shape of the four sides. Separately, some have the width of the joint 3 and the shape of one side, or the width of the joint 3 and the shape of two opposite sides. In addition to the above, there are some which come into contact with specific places in a spot manner. These are, for example, an introduction to TAB technology Kenzo Hatada, Industrial Research Institute Publishing 2
It has the same structure as the outer lead bonding tool described in “Outer Lead Bonding Tool” on page 32.

[0005] The joining method using such a joining tool has the following problems. (1) The tool is Inconel (Ni-Cr-Fe alloy)
Etc., but it is difficult to obtain the flatness of the surface, and a uniform force is not applied to the joint 3.
This causes uneven bonding such as a portion where the pressure is small and appears to float. (2) In the case of joining in spots or in units of one side, there is not much problem of flatness, but mass productivity is reduced. (3) Even under the best conditions, the joining is performed by a tool having a plane shape of four sides of the joining portion 3, and only one piece can be joined at a time, so that productivity is extremely poor.

[0006]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems in the prior art, and can easily align an FPC or TAB tape and a lead frame with a simple process with high reliability and productivity. An attempt is made to provide a manufacturing method that can be joined.

[0007]

That is, the present invention provides an FP
When a composite lead frame is manufactured by connecting a C or TAB tape and a lead frame, an FPC or TA is placed on a mold having alignment means by using the alignment means.
The composite lead for connecting the FPC or TAB tape and the lead frame by heating and press-contacting the B tape and the lead frame by defining a mutual position and overlapping each other, and then pressing the upper part of the B tape and the lead frame by a hot press method via an elastic body having high thermal conductivity. A method for manufacturing a frame is provided.

Here, the mold has positioning pins as positioning means, and the positioning holes of the FPC or TAB tape and the lead frame are inserted into the positioning pins of the mold to perform positioning. Is preferred.

The method of the present invention will be described below with reference to a preferred embodiment shown in the drawings. FIG. 3 is a diagram illustrating the method of the present invention. A preferred embodiment of the method of the present invention comprises the following steps, as shown in FIG.

First, the FPC or TAB tape 20 and the lead frame 50 are superimposed on the positioning die 19 having the positioning means with the mutual positions thereof being determined.

Next, the FPC or TAB tape 20 and the lead frame 50 are heated and pressed from above the superimposed upper portion via the highly thermally conductive elastic body 16 with a flat plate 18 having a heater for heating, and the copper of the FPC or TAB tape 20 is pressed. Foil pattern 4
And the tip of the inner lead 5 of the lead frame 50 are joined by local heating diffusion, solder joining, eutectic joining, or the like.

Preferably, the positioning die 19 is placed on the press table 17 and is heated and pressed between the flat plate 18 with a heater for heating and the press table 17.

The positioning mold 19 is preferably made of the same material as that of the lead frame 50 so that the fluctuation due to thermal expansion is always constant between the lead frame 50 and the positioning mold 19. The surface of the alignment mold 19 may be plated with chromium or the like to prevent generation of oxide scale due to heating.

The positioning means on the positioning mold 19 is not particularly limited, but preferably, as illustrated in FIG. 3, positioning pins 140, 1 protruding from the surface of the positioning mold 19.
50 FPC or TAB tape 20 respectively
And the copper foil pattern 4 of the FPC or TAB tape 20 and the inner leads 5 of the lead frame 50.
Are arranged so as to be superimposed on a position where the joints are connected by the joint portion 3.

As shown in the cross-sectional view of FIG. 2A, the structure of the joint 3 is such that the copper foil pattern 4 on the polyimide film 13 of the FPC or TAB tape 20 is below, and the inner leads 5 of the lead frame 50 are above. 2B, the end of the copper foil pattern 4 is protruded from the end face of the polyimide film 13 of the FPC or TAB tape 20 as shown in the cross-sectional view of FIG. 5 may be configured to overlap the lower end on the lower side.

The thermocompression bonding of the bonding portion 3 is not particularly limited as long as it is a method of melting and solidifying a low melting point metal.
Preferably, there is the following method. (1) Au-Sn bonding method The tip of the inner lead 5 of the lead frame 50 is partially plated with Sn in advance, and the FPC or TAB tape 20 is used.
Au plating is applied to the tip of the copper foil pattern 4, and the Sn plating and the Au plating are overlapped and heated and pressed to perform eutectic bonding. (2) Au-solder eutectic bonding method In advance, the tip of the inner lead 5 of the lead frame 50 is partially solder-plated with a Sn / Pb alloy, and the tip of the copper foil pattern 4 of the FPC or TAB tape 20 is Au-plated and solder-plated And the Au-plated portion are superimposed on each other and heated and pressed to form a eutectic joint.

The high thermal conductive elastic body 16 is made of a material having high thermal conductivity and elasticity, such as a heat-resistant Teflon sheet, a heat-resistant silicon rubber sheet, or a heat-resistant glass fiber-filled Teflon sheet. Thickness 0.1-5
mm is preferable, and the high thermal conductive elastic body 16 is connected to the lead frame 50 and the FPC or TAB tape 20 at the time of heating and pressing.
The heat conductive material and the cushion material between the press table 17 and the flat plate 18 with a heater for heating can be used so that the joint 3 can be heated and pressed with uniform force over the entire surface.

[0018]

The present invention will be described below with reference to examples.
The present invention is not limited to these examples.

(Example 1) A lead frame and an FPC were joined using the structure shown in FIG. First, the FPC 20 is set on the alignment mold 19. Alignment mold 19
Positioning pins 140 and 150 are protrudingly provided on the surface, and a positioning hole 14 formed in the FPC 20 is inserted into the positioning pin 140 to place the FPC on the positioning mold 19.
Position and set 20.

Next, the lead frame 50 is set on the positioning mold 19. The positioning hole 15 formed in the lead frame 50 is inserted into the positioning pin 150 on the positioning die 19 to be positioned and set.

Next, the FPC 20 and the lead frame 50 in which the high thermal conductive elastic body 16 is superimposed on the positioning mold 19 are arranged.
And cover from the top. Above the high thermal conductive elastic body 16, a flat plate 18 with a heater for heating is fixedly provided. In this state, the press table 17 is disposed so as to be able to move up and down by hydraulic pressure or pneumatic pressure. When the positioning die 19 on which the FPC and the lead frame are mounted is mounted on the surface thereof, the press table 17 is raised, and the press heater 17 is provided. Press on flat plate 18. Pressing is performed while applying a force upward until a certain pressure is reached, and after holding for a certain period of time, the press table 17 is lowered with the FPC and the lead frame placed thereon. The flat plate 18 with a heater for heating is turned on / off by a thermostat,
The temperature is always kept constant. The press time is managed by a timer.

The positional relationship between the FPC 20 and the lead frame 50 is determined by positioning pins 140 and 150 provided on the positioning die 19, and does not change during pressing.

The high thermal conductive elastic body 16 is a glass fiber reinforced Teflon sheet having a thickness of 0.05 to 0.1 mm.

The lead frame used, plated with Sn in 7μm thickness at the tip of the inner lead 5 of the lead frame 50 of the 304 ^pin, FPC is the 304 ^pin FPC 2
The copper foil pattern 4 of No. 0 was plated with Au plating having a thickness of 1.0 μm. The material of the lead frame 50 is
The FPC 20 is made of oxygen-free copper to which 0.15% Zr is added and has a thickness of 0.15 mm. The FPC 20 has a polyimide film 13 having a thickness of 50 μm and a copper foil pattern having a thickness of pure copper foil of 35 mm.
μm. The material of the positioning mold 19 was pure copper, the same as that of the lead frame 50, and the fluctuation due to thermal expansion was always constant. Further, chrome plating having a thickness of 10 μm is applied to the entire surface in order to prevent generation of oxide scale due to heating.

The heating and pressing conditions are as follows:
Temperature is 350 ° C, time is 10 seconds, pressure is 1.5kg / c
It was carried out in m ^2. The arrangement of the joints 3 is as shown in FIG. 2A, and the inner leads 5 are superimposed on the copper foil pattern 4.

By heating and pressing at a temperature of 350 ° C. for 10 seconds, Sn having a melting point (mp) of 232 ° C. is melted and flows out from the bonding interface. At this time, it flows out while creating the first Au-Sn eutectic composition (about Sn 90%, Au 10%, mp = 217 ° C). Next, a second Au-Sn eutectic composition (about S
n 80%, Au 20%, mp = 252 ° C.) and a third Au—Sn eutectic composition (about Sn 60%, Au 20%, mp
= 309 ° C) and the bonding was completed while creating the final fourth Au-Sn eutectic composition (about 20% Sn, 80% Au). The temperature of 350 ° C. is the temperature of the flat plate 18 with a heater, and the temperature of the lead frame 50 is 3
It reached 30 ° C. The formation of the above-mentioned eutectic composition is sequentially started, but at the final temperature of 330 ° C., the average composition of the plating basis is settled and the bonding is completed (Sn 7 μm, Au
The average composition of the basis weight of the plating having a thickness of 1.0 μm is 70% of Sn). Bonding pressure is 0-1.5kg in 0-5 seconds
It was set to rise up.

The pressure rise curve was managed by a timer. 1
When the heating heater 18 was turned off after the elapse of the bonding time of 0 second, the temperature instantaneously dropped. The switch was operated in conjunction with the timer, and then the press pressure was released 5 seconds after the switch was turned off. After a lapse of 5 seconds, the temperature instantaneously dropped to 250 ° C., and the joint 3 was already solidified and the joint 3 was completely joined without loosening.

Example 1 A lead frame made of Fe-42% Ni alloy and having a thickness of 0.15 mm was used as a lead frame.
Bonding was performed in the same manner as described above. The joining conditions were Fe-42% N
Example 1 was carried out in the same manner as in Example 1 except that the temperature of the flat plate 18 with a heater for heating was set to 370 ° C. because the i-alloy was inferior in heat conductivity to the copper system. Complete bonding was obtained in the same time as in Example 1.

In the conventional method, the joining is performed for about 5 seconds on each side of the joining portion 3. Therefore, it takes 5 seconds × 4 sides × 3PC = 60 seconds to join the 3PC1 frame, but in the case of the method of the present invention, Since the joining of one frame is completed in a joining time of about 15 seconds, the joining of the same 3PC1 frame takes only 15 seconds and can be done in about 1/4 time.

[0030]

According to the method of the present invention, the following effects can be obtained. (1) Since joining can be performed for each frame, joining productivity is high. (2) Since bonding is performed in frame units, there is little variation per bonded piece, and bonding reliability is high. (3) FPC or TAB because alignment pins are used
The alignment between the tape and the lead frame is very easy. Conventionally, the image processing method is used for alignment,
It took about 15 seconds per PC.

[Brief description of the drawings]

FIG. 1 is a plan view of a composite lead frame.

FIG. 2 is a cross-sectional view showing a structure of a joint between an inner lead and a copper foil pattern.

FIG. 3 is a diagram illustrating the method of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 LSI mounting part (die pat) 2 FPC or TAB tape end part 3 Joining part 4 Copper foil pattern 5 Inner lead 6 Tie bar 7 Cushion lead 8 Cushion lead 9 Outer frame part 10 Tie bar 11 Cushion lead attachment part 12 Outer lead 13 Polyimide film 14 Alignment hole 140 Alignment pin 15 Alignment hole 150 Alignment pin 16 High thermal conductive elastic body 17 Press table 18 Average with heater 19 Alignment mold 20 FPC or TAB tape 50 Lead frame

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Kenji Yamaguchi 3550 Kida Yomachi, Tsuchiura City, Ibaraki Pref.

Claims (2)

(57) [Claims] When a composite lead frame is manufactured by connecting an FPC or TAB tape and a lead frame, an FPC or TAB tape and a lead frame are placed on a mold having alignment means by using the alignment means. Are placed on top of each other, and then heated and pressed by hot pressing from above through an elastic body with high thermal conductivity to form FP.
A method for manufacturing a composite lead frame, comprising connecting a C or TAB tape and a lead frame. 2. The positioning means is a positioning pin, one of which is inserted into a positioning hole of an FPC or TAB tape and the other of which is inserted into a positioning hole of a lead frame. 2. A method for manufacturing a composite lead frame according to claim 1, wherein the mutual positions of the lead frame and the FPC or TAB tape are determined.