Metal working – Means to assemble or disassemble – Means to disassemble electrical device
Reexamination Certificate
2000-05-26
2003-04-01
Eley, Timothy V. (Department: 3723)
Metal working
Means to assemble or disassemble
Means to disassemble electrical device
C029S840000, C029S860000, C029S611000, C029S613000
Reexamination Certificate
active
06539618
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention pertains to a repair approach in electronics assemblies, and specifically, to a tool for the removal of solder-attached, non-underfilled ball grid array electronic packages from printed wiring boards
2. Description of the Prior Art
In electronics, the package contains one or more components. Packages, in a traditional sense, are the “containers” of integrated circuits (ICs) or multi-chip modules (MCMs) that might be soldered onto a printed wiring board. They are limited in physical size, as they must be large enough to be handled by humans, but small enough to mount within other assemblies. The simultaneous growth of signal count and increase in operating frequency of contemporary single chip packages (SCPs) and MCMs demands spatially efficient, adequate, and electrically effective packages, both for test and operation.
Packages can be classified as through-hole or surface mount. Surface mount packages, as the name implies, attach to the surface of a board and do not perforate the board with pins. Recently, the quantity of surface mount packages used in assemblies worldwide exceeded through-hole packages. Ball grid arrays (BGAs) is one of a number of surface mount packages that is becoming increasingly popular. The ball grid array (
FIG. 1
) is similar to a pin grid array, except that solder balls replace the pins. Rather than penetrate the board with each pin, as in the case of through-hole packages, BGAs are attached by solder reflow action to the surface of a board onto mating land patterns.
The ball grid array (BGA) package may be viewed as the single most important development in packaging this decade. Although BGAs represent a very small percentage of the total package usage today, BGA technology is one of the fastest rising technologies in the advanced packaging field. BGAs have been applied to workstation and computer processors, complex gate arrays, field programmable gate arrays, and consumer and automotive applications.
BGAs can support higher numbers of I/O much more efficiently than perimeter-based packages. BGAs have many other important advantages. As a surface-mount approach, they have improved routability over through-hole approaches of similar complexity since pins do not penetrate the mounting board, thereby occluding valuable routing real estate. Their electrical performance is significantly better than other traditional package types, and BGA packages are smaller and lighter than other package types. They are less fragile than quad flat packages, which have delicate leads that if bent even slightly require special handling for assembly.
One of the most striking advantages of BGAs over other package styles is ease of assembly (notwithstanding the application of underfill) due to the self-alignment property of solder ball arrays. The surface tension of solder acts to bring the array of solder connections into alignment with the mating pattern of contacts on the board onto which a BGA is assembled. As shown in
FIG. 2
, misalignments (which can be as severe as half the ball diameter) can be corrected as the assembly is heated to the solder reflow temperature point.
By far the most common type of BGA in current use is the plastic ball grid array (PBGA) (FIG.
3
). The PBGA involves forming a BGA package from circuit board material, usually BT resin. One side of this board contains a BGA I/O pattern, and the other side accommodates an IC direct chip attachment, usually through wire bonding. In the formation of the BGA, the component is mounted and encapsulated, and the solder balls are then attached in one of several ways, resulting in a finished assembly.
The most significant problem in BGA application is thermal expansion mismatch. In the case of PBGAs, the problem occurs within the package itself In the region of the package where silicon is mounted, the expansion of the board material is constrained relative to its own expansion in silicon-free regions. The differential expansion sometimes creates cracking in solder balls in the boundary between the two regions. Overall package expansion can occur, particular in metal and ceramic BGAs, in which cases the stress is an increasing function of size. Fractures often occur at solder ball interfaces.
Several concepts have emerged to deal with mismatch problems. A more common practice involves the introduction of an underfill, a polymer injected underneath the mounted package, which surrounds the solder balls and creates a much more robust mechanical attachment. It is only with reluctance that assemblers use underfill, though, as most underfill compounds render the associated BGAs non-repairable, and the underfill application process is time-consuming and problematic.
The removal of BGA packages currently involves using a hot air machine with hoses and appropriately shaped nozzles to guide air that is pre-heated to solder-melting temperatures underneath the package. When the hot air is directed adequately with enough duration to melt the solder, it can then be removed with care. The present invention is a compact hand-held tool that simplifies this task. It basically consists of a heated metal wire that is slid through the interface between the BGA packaged IC or MCM and the printed wiring board. A thin Teflon sheet follows the wire to prevent the molten solder from re-solidifying.
SUMMARY OF THE INVENTION
The present invention is an efficient, simple, and economical.tool and method for removing ball grid array packaged integrated circuitry or multi-chip modules from printed circuit boards. The tool consists of a wire stretched between the tips of a two tine fork-shaped instrument and a thin (Teflon) sheet filling the area between the tines. The wire is heated by a constant current source to beyond the melting point of the solder system. The Teflon sheet is used to interrupt the molten solder, which would otherwise have a tendency to collapse onto itself after melting. After the tool is pushed through the entire solder array, the BGA is freed from its attachment and can be easily removed. The tool's use is limited to assemblies that do not have underfill.
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Callahan Kenneth E.
Eley Timothy V.
Nguyen David
Skorich James M.
The United States of America as represented by the Secretary of
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