Electrical connectors – Preformed panel circuit arrangement – e.g. – pcb – icm – dip,... – With provision to conduct electricity from panel circuit to...
Reexamination Certificate
2000-08-10
2003-02-25
Ta, Tho D. (Department: 2833)
Electrical connectors
Preformed panel circuit arrangement, e.g., pcb, icm, dip,...
With provision to conduct electricity from panel circuit to...
C439S067000
Reexamination Certificate
active
06524115
ABSTRACT:
FIELD OF THE INVENTION
The invention relates to interconnection between integrated circuit devices and other similar devices or test structures used for burn-in or evaluation of the devices. More specifically, the invention relates to geometrical arrays of contacts, distributed through flexible films and elastomers to establish reliable, low force electrical interconnection between electronic components.
BACKGROUND OF THE INVENTION
The introduction of solid-state semiconductor electronics provided the opportunity for progressive miniaturization of components and devices. One of the benefits of such miniaturization is the capability of packing more components into a given space. This increases the features, versatility and functionality of an electronic device, usually at lower cost. A drawback of such advances is the reduction in spacing between contacts on one device and the need for accurate alignment with corresponding contacts on a second device to provide reliable electrical interconnection between the two. Modern technology, using VLSI electronics, challenges design engineers to provide such fine interconnection structures that electrical isolation between individual connectors becomes a primary concern. Current designs, for example, include spaces as low as 0.15 mm between contacts. Secondary to connector isolation is the inevitable reduction in pliability of insulating material, between electrical contacts, as the distance between contacts decreases. Thus, a geometrical array of contacts held together by a planar insulating material allows less independent movement between contacts the closer they approach each other. Absent freedom of movement, individual contacts may fail to connect to a target device, especially if some of the device contacts lie outside of a uniform plane. Lack of planarity causes variation in the distance between the device contacts and an array of contacts intended to mate with the device contacts. Accurate engagement by some contacts leaves gaps between other contacts unless independent contacts have freedom to move across such gaps. Alternatively the connecting force between an array of contacts and device contacts must be increased, for reliable interconnection, with resulting compression and potential damage for some of the contacts.
Interconnection of electronic components with finer and finer contact spacing or pitch has been addressed in numerous ways along with advancements in semiconductor device design. Introduction of ball grid array (BGA) devices placed emphasis on the need to provide connector elements with space between individual contacts at a minimum. One answer, found in U.S. Pat. Nos. 5,109,596 and 5,228,189, describes a device for electrically connecting contact points of a test specimen (circuit board) to the electrical contact points of a testing device using an adapter board having a plurality of contacts arranged on each side thereof. Cushion-like plugs made from an electrically conductive resilient material are provided on each of the contact points to equalize the height variations of the contact points of the test specimen. An adapter board is also provided made of a film-like material having inherent flexibility to equalize the height variations of the contact points of the test specimen. Furthermore, an adapter board is provided for cooperating with a grid made of an electrically insulated resilient material and having a plurality of plugs made from an electrically conductive resilient material extending therethrough. Successful use of this device requires accurate registration of contacts from the test specimen, through the three layers of planar connecting elements to the testing device.
U.S. Pat. Nos. 5,136,359 and 5,188,702 disclose both an article and a process for producing the article as an anisotropic conductive film comprising an insulating film having fine through-holes independently piercing the film in the thickness direction, each of the through-holes being filled with a metallic substance in such a manner that at least one end of each through-hole has a bump-like projection of the metallic substance having a bottom area larger than the opening of the through-hole. The metallic substance serving as a conducting path is prevented from falling off, and sufficient conductivity can be thus assured. While the bump-like projections of the anisotropic conductive films, previously described, represent generally rigid contacts, U.S. Pat. Nos. 4,571,542 and 5,672,978 describe the use of superposed elastic sheets over a printed wiring board, to be tested, and thereafter applying pressure to produce electroconductive portions in the elastic sheet corresponding to the contact pattern on the wiring board under test. In another example of a resilient anisotropic electroconductive sheet, U.S. Pat. No. 4,209,481 describes a non-electroconductive elastomer with patterned groupings of wires, electrically insulated from each other, providing conductive pathways through the thickness of the elastomer. Other known forms of interconnect structure may be reviewed by reference to United States Patents including U.S. Pat. Nos. 5,599,193, 5,600,099, 5,049,085, 5,876,215, 5,890,915 and related patents.
In addition to the problem, mentioned previously, of interconnection failure caused by gaps between contacts, an additional cause of interconnection failure occurs by occlusion of a metal contact due to surface contamination with e.g. grease, non-conducting particles or a layer of metal oxide. Such an oxide layer results from air oxidation of the metal. Since oxide layers generally impede the passage of electrical current, reliable contact requires removal or penetration of the oxide layer as part of the interconnection process. Several means for oxide layer penetration, towards reliable electrical connection, may be referred to as particle interconnect methods as provided in U.S. Pat. Nos. 5,083,697, 5,430,614, 5,835,359 and related patents. A commercial interconnect product, described as a Metallized Particle Interconnect or MPI, is available from Thomas & Betts Corporation. The product is a high temperature, flexible, conductive polymeric interconnect which incorporates piercing and indenting particles to facilitate penetration of oxides on mating surfaces. Another commercial, electronic device interconnection product, available from Tecknit of Cranford, N.J., uses “Hard Hat” and “Fuzz Button” contacts in selected arrays. U.S. Pat. Nos. 4,574,331, 4,581,679 and 5,007,841 also refer to the “Fuzz Button” type of contact.
The previous discussion shows that interconnection of electronic devices has been an area subject to multiple concepts and much product development in response to the challenges associated with mechanical issues of interconnection and resultant electrical measurements. Regardless of advancements made, there is continuing need for improvement in three key areas, namely registration between interconnecting devices and electronic components, flexibility of contact sets for reliable device interconnection and minimization of the force required for reliable interconnection. In view of the continuing needs, associated with interconnect structures, the present invention has been developed to alleviate drawbacks and provide the benefits described below in further detail.
SUMMARY OF THE INVENTION
The present invention provides a compliant interconnect assembly for effecting reliable electrical connection between electronic devices, with contact forces much lower than previously attainable. Connection schemes, that include the compliant interconnect assembly, may be temporary for testing a semiconductor device that may be addressed via the conductive traces of a circuit used for e.g. test and burn-in.
In addition the compliant interconnect may be used as a contactor, a production socket, a burn-in socket, a probing device, a board to board interconnect, as a device to device interconnect and similar applications. The compliant interconnect is a low profile, rugged structure that forms solderless, releasable and remateable conn
Bumb, Jr. Frank E.
Gates Geoffrey William
3M Innovative Properties Company
Ball Alan
Ta Tho D.
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