[Field of Utilization in Industry]
The present invention relates to a to-be-mounted electronic component to which functional alloy plating using a bonding material for mounting is applied with a substitute bonding material for solder (tin-lead alloy), and aims at providing alloy plating which has been put to a practical use in such a way that the function of existing alloy plating of this type has been significantly improved to eliminate toxic plating from various kinds of electronic components for use in electronic devices so that it is useful in protecting the environment.
[Background of the Invention]
As solder which does not use lead (Pb) (Pb-free solder), various new bonding agents have been developed and their properties become apparent. And, the stage is proceeding to the development of their manufacturing methods. Tin (Sn)-bismuth (Bi), Sn-indium alloy (In), Sn-zinc alloy (Zn), Sn plating etc. are considered as Pb-free solder to devices. The cost for the Sn—In alloy among them is extremely high, about 25 times the cost for Sn—Bi. The Sn—Zn alloy has a problem on the solderability after heat resistance because Zn is prone to be oxidized. This leaves Sn—Ag, Sn—Bi and Sn.
Bi on copper may be thermally diffused at the time of reflow and may be peeled, so that Sn—Bi for devices should have nickel applied as a base in order to avoid the peeling.
If a coat offset (melt-originated offset) occurs when a surface-mounting device is melted, the bonding surface has a rough surface, so that the bonding surface becomes smaller, thus lowering the bonding strength. Prevention of a melt-originated offset which makes organic eutectoid in a coat extremely small is attempted by applying plating according to this invention.
[Prior Art]
Conventionally, solder (tin-lead alloy) has been used for a long time as a bonding material for mounting electronic device components. Recently, the harmfulness of lead has been noticed mainly in America and Europe and removal of lead from electronic devices has progressed rapidly.
Meanwhile, in Japan has already started a movement of voluntary removal mainly by the electronics industry.
Electroplating is applied to most of materials for to-be-mounted electronic components as tinning. Therefore, there is a pressing need to industrialize plating of substitute alloys for the industrial growth.
[Problem to be Solved by the Invention]
As solder which is an essential bonding material for the aforementioned electronic components contain lead (Pb), however, when electronic devices are disposed of, lead would be melted and seep into groundwater from a junk yard, raising a problem of environmental pollution, unless electronic components having to-be-mounted parts containing solder's lead are removed.
[Means for Solving the Problem]
Accordingly, it is an object of this invention to overcome the problem of the prior art and to provide electronic components to be on which very practical alloy plating for bonding that is the existing alloy plating of this type which has been improved significantly is applied using a substitute metal for lead in solder alloy plating.
The first of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that with Sn as a base, one of Bi, Ag and Cu is selected, a Bi content to the Sn is set to 1.0% or less, the Bi content to the Sn is set to 2.0 to 10.0%, an Ag content to the Sn is set to 1.0 to 3.0%, the Ag content to the Sn is set to 3.0 to 5.0%, the Ag content to the Sn is set to 8.0 to 10.0%, or a Cu content to the Sn is set to 0.5 to 1.0%, and an electrolytic process is performed with a special waveform.
The second of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with a Bi content to Sn whose content is 99.0% or greater being set to 1.0% or less and with a special waveform.
The third of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with a Bi content to Sn whose content is 98.0 to 90.0% being set to 2.0 to 10.0% and with a special waveform.
The fourth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with an Ag content to Sn whose content is 99.0 to 97.0% being set to 1.0 to 3.0% and with a special waveform.
The fifth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with an Ag content to Sn whose content is 97.0 to 95.0% being set to 3.0 to 5.0% and with a special waveform.
The sixth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with an Ag content to Sn whose content is 92.0 to 90.0% being set to 8.0 to 10.0% and with a special waveform.
The seventh of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an IC chip is wire-bonded to a lead frame and outer leads exposed outside a molded IC package are subjected to an electrolytic process with a Cu content to Sn whose content is 99.5 to 99.0% being set to 0.5 to 1.0% and with a special waveform.
The eighth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with a Bi content to Sn whose content is 99.0% or greater being set to 1.0% or less and with a special waveform.
The ninth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with a Bi content to Sn whose content is 98.0 to 90.0% being set to 2.0 to 10.0% and with a special waveform.
The tenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with an Ag content to Sn whose content is 99.0 to 97.0% being set to 1.0 to 3.0% and with a special waveform.
The eleventh of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with an Ag content to a content of 97.0 to 95.0% being set to 3.0 to 5.0% and with a special waveform.
The twelfth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with an Ag content to a content of 92.0 to 90.0% being set to 8.0 to 10.0% and with a special waveform.
The thirteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that an electrode pattern of a printed circuit board is subjected to an electrolytic process with a Cu content to Sn whose content is 99.5 to 99.0% being set to 0.5 to 1.0% and with a special waveform.
The fourteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with a Bi content to Sn whose content is 99.0% or greater being set to 1.0% or less and with a special waveform.
The fifteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with a Bi content to Sn whose content is 98.0 to 90.0% being set to 2.0 to 10.0% and with a special waveform.
The sixteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with an Ag content to Sn whose content is 99.0 to 97.0% being set to 1.0 to 3.0% and with a special waveform.
The seventeenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with an Ag content to Sn whose content is 97.0 to 95.0% being set to 3.0 to 5.0% and with a special waveform.
The eighteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with an Ag content to Sn whose content is 92.0 to 90.0% being set to 8.0 to 10.0% and with a special waveform.
The nineteenth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that a chip tantalum capacitor is wire-bonded to a lead frame and outer leads exposed outside the chip tantalum capacitor are subjected to an electrolytic process with a Cu content to Sn whose content is 99.5 to 99.0% being set to 0.5 to 1.0% and with a special waveform.
The twentieth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with a Bi content to Sn whose content is 99.0% or greater being set to 1.0% or less and with a special waveform.
The twenty-first of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with a Bi content to Sn whose content is 98.0 to 90.0% being set to 2.0 to 10.0% and with a special waveform.
The twenty-second of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with an Ag content to Sn whose content is 99.0 to 97.0% being set to 1.0 to 3.0% and with a special waveform.
The twenty-third of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with an Ag content to Sn whose content is 97.0 to 95.0% being set to 3.0 to 5.0% and with a special waveform.
The twenty-fourth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with an Ag content to Sn whose content is 92.0 to 90.0% being set to 8.0 to 10.0% and with a special waveform.
The twenty-fifth of this invention is functional alloy plating using substitute bonding material for Pb and electronic component to be mounted to which the functional alloy plating is applied, characterized in that general electronic device component materials including a component material which needs plating for bonding and a general component material which needs plating as a functional component are subjected to an electrolytic process with a Cu content to Sn whose content is 99.5 to 99.0% being set to 0.5 to 1.0% and with a special waveform.
[Embodiment]
[Significance of Special Waveform]
A description will now be given of the aforementioned “electrolytic process with a special waveform”. First, typical electroplating is DC plating, i.e., plating with a voltage having an AC voltage rectified by a rectifier.
To perform plating, it is necessary to combine and add several types of organic additives into a plating solution so that the crystal grain size of metal to be deposited does not become resin particle size.
Of course, those organic materials become eutectoid at the same time as the metal to be plated, causing many defects on their functions as bonding materials.
The “electrolytic process with a special waveform” in this invention improves those shortcomings, and an additive to be added into a plating solution is only a slight amount of a surface active agent which is not decomposed and disposed, and this special waveform serves as an organic additive.
In this invention, the special waveform is a pulse waveform which is acquired for an electrolytic process from a current that has been rectified with a thyristor 6-phase half wave. Thus, the electrolytic process uses a pulse waveform which can cycle between positive and negative.
The following shows a table of the types of mass-producible platings.
As there are different coat characteristics to be acquired depending on whether the lead types of devices to be used are lead lines, a lead frame or leadless, they should be selectively used, but the added values of the devices differ device by device so that a cost-based selection is also considered as an important factor.
In the comparison of the costs for plating materials, the cost for the base acid is high even if an inexpensive metal is used, so that the cost does not decrease as indicated in the comparison of the prices of metals. A further variation is seen when it is run as plating.
Then, the following table shows the evaluation of Pb-free coats as coats.
The following table shows a list of the evaluation of the individual coats.
The following table shows the costs for the individual coats.
While the samples shown above had a nickel (Ni) base to avoid diffusion on copper, Sn—Ag showed such a phenomenon that oxidization on Ni through Ag at the time of heat resistance lowered the bondability. In this respect, it is contemplated that copper (Cu) is suitable as the base for Sn—Ag. Further, heat-resistance-originated discoloration and melt-originated offset also occurred. To cope with this melt-originated offset, it is necessary to obtain Sn—Ag plating containing 85% or more of Ag, which is naturally a factor to increase the cost. Slight segregation is seen on the surface of Sn—Bi. Sn—Ag and Sn-special waveform plating still suffer poor solution efficiencies and the line speeds remain about a half the speed of the current special-waveform plating. Although solution conditions were so set as to provide the optimal appearance in the implementation of the scheme, improvements can be made on the density of the solution, the density of the additive, stirring and so forth. In the case of surface mounting, there may be a question on the behavior of Bi, such as segregation or diffusion. In this respect, Bi in the Sn-special waveform plating has a minute amount and serves to adjust the deposition of the plated coat so that it does not seem to raise a problem on segregation or diffusion.
The following gives the results of the evaluation of samples of Sn—Ag, Sn—Bi and Sn plating to chip tantalum frames.
(1) Plating Specifications
(5) Bonding Strength Measuring Conditions
(6) Plating Thickness Measuring Portion
(7) Measuring Portions
As shown in
With regard to the evaluation coats, evaluation method and measuring method, the results of the comparison of the characteristics of the individual Pb-free coats as shown in Tables 14 to 16 were obtained.
Examples of this invention will now be described with reference to the accompanying drawings. In the diagrams, “1” is a lead frame where a mount component, such as an IC chip, is mounted, and which has an island portion 2 in the center portion and a plurality of outer leads at the periphery.
“3” denotes outer leads which become to-be-plated portions and protrude outward of the IC package, and “4” is a ball lead portion which becomes a to-be-plated portion as external leads of CSP.
While alloy plating to be applied to the aforementioned to-be-plated portions contains Sn and a plating material other than lead, and the composition is as follows. The set ratios are Bi=1.0% with respect to Sn=99.0% in the first example, and Bi=2.0 to 10.0% with respect to Sn=98.0 to 90.0% in the second example. The ratio is set to Ag=1.0 to 3.0% with respect to Sn=99.0 to 97.0% in the third example. The ratio is set to Ag=3.0 to 5.0% with respect to Sn=97.0 to 95.0% in the fourth example. The ratio is set to Ag=8.0 to 10.0% with respect to Sn=92.0 to 90.0% in the fifth example. The ratio is set to Cu=0.5 to 1.0% with respect to Sn=99.5 to 90.0% in the sixth example.
“5” is an IC chip, a mount component, to be mounted on the lead frame 1, “5′” is an LSI chip, and “5″” is a chip tantalum capacitor. “6” denotes inner leads, and “7” is a package which has the IC chip 5 or the LSI chip 5′ molded with a resin.
In
[Specific Examples of Steps]
(1) IC Fabrication Process
[Effect of the Invention]
With the above-described structure, this invention eliminates Pb from a solder material as a bonding material which is essential for electronic components in the production of electronic devices, thereby preventing a possible pollution problem such that when electronic devices which become unnecessary are disposed of, Pb leaks and seeps into groundwater.
In mounting electronic components, alloy plating equivalent to or greater than Pb can be acquired without using Pb but by using other bonding materials than Pb.
A first measuring portion
B second measuring portion
a third measuring portion
b fourth measuring portion
1 lead frame
2 island portion
3 outer leads
4 ball lead portion
5 IC chip
6 inner leads
7 IC package
8 IC wafer
9 printed circuit board
10 electrode pattern
11 soldering bonding portion
Number | Date | Country | Kind |
---|---|---|---|
11-164307 | May 1999 | JP | national |
The present application is a divisional application of U.S. application Ser. No. 09/566,125 filed May 5, 2000 now U.S. pat. No. 6,478,944, and which claims priority of Japanese Application No. 11-164307, filed May 7, 1999. The entire disclosure of application Ser. No. 09/566,125 is considered as being part of the disclosure of this application, and the entire disclosure of application Ser. No. 09/566,125 is expressly incorporated by reference herein in its entirety.
Number | Name | Date | Kind |
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5643432 | Qiu | Jul 1997 | A |
5674374 | Sakurai et al. | Oct 1997 | A |
5759379 | Cavallotti et al. | Jun 1998 | A |
5948235 | Arai | Sep 1999 | A |
6203684 | Taylor et al. | Mar 2001 | B1 |
6478944 | Ishiyama | Nov 2002 | B1 |
Number | Date | Country |
---|---|---|
0474499 | Mar 1992 | EP |
63187654 | Aug 1988 | JP |
63-49382 | Oct 1988 | JP |
2543619 | Jul 1996 | JP |
Number | Date | Country | |
---|---|---|---|
20030141192 A1 | Jul 2003 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 09566125 | May 2000 | US |
Child | 10256010 | US |