Conveyorized vacuum applicator and method of applying a dry...

Radiation imagery chemistry: process – composition – or product th – Imaging affecting physical property of radiation sensitive... – Making electrical device

Reexamination Certificate

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C430S319000, C428S901000

Reexamination Certificate

active

06610459

ABSTRACT:

The present invention is directed to an automatic conveyorized vacuum applicator and method of operation thereof having utility in the application of dry film photoresist-forming materials, such as photoresists and solder masks, to surfaces of printed circuit boards or other substrates, to assure complete conformance of the dry films around raised circuit traces and irregular surface contours. The applicator and method have particular utility for conveying and for applying vacuum, heat, and mechanical pressure to printed circuit boards or other substrates that prior to such application have had dry film loosely applied to at least one of the surfaces thereof as discrete cut sheets within the confines of the substrate.
Primary imaging photoresists and secondary imaging solder masks are among the most widely used photoimageable materials in the manufacture of printed circuit boards. A primary imaging photoresist is used in the creation of the printed circuitry itself, whereas a solder mask is used to protect the printed circuitry during soldering of components onto the board.
A primary photoresist is a hard, temporary layer of non-conductive material which covers the metal surface of a copper-clad substrate that later becomes the printed circuit board. The photoresist is patterned in such a way so as to produce a resist stencil around which the printed circuit tracks are formed.
More specifically, primary photoresists, typically, are formed from a layer of photoimageable composition which is applied to the surface of a copper-clad board. The photoimageable composition is exposed to actinic radiation which is patterned by means of a template or artwork. Subsequent to exposure, the photoimageable layer is developed in an organic solvent, aqueous, or semi-aqueous solution which washes away either exposed or unexposed portions of the layer (depending on whether the photoimageable material is positive-acting or negative-acting). Thereafter, the circuit traces are formed by either electroplating or etching. In a typical plating procedure, the areas devoid of photoresist that become the circuitry are built up from the board surface by electroplating copper thereon. After protecting the electroplated copper layer, the remaining photoresist is stripped away in an organic solvent, aqueous, or semi-aqueous solution, and the newly exposed areas of metal are then selectively removed in an etching solution, leaving behind the pattern plated copper circuit lines. In a typical etching procedure, the metal in the areas devoid of photoresist is selectively removed in an etching solution, leaving behind the residual portions of the etched metal layer as the circuit traces after the primary resist is stripped away.
A solder mask, on the.other hand, is a hard, permanent layer of non-conductive material which covers the surface of a printed circuit board or other substrate, encapsulating the traces of the printed circuitry itself. The solder mask is patterned to fully cover the circuitry, except for those portions intended to be exposed, e.g., for soldering to another component.
More specifically, solder masks, typically, are formed from a layer of photoimageable composition which is applied to a surface of the printed circuit board. Similar to primary imaging resists, the photoimageable layer is exposed to actinic radiation which is patterned by means of a template or artwork. Subsequent to exposure, the photoimageable layer is developed in an organic solvent, aqueous, or semi-aqueous solution which washes away either exposed or unexposed portions of the layer (again depending upon whether the photoimageable material is positive-acting or negative-acting). The portion of the layer which remains on the surface is then cured, e.g., with heat and/or UV light, to form a hard, permanent solder mask intended to protect the printed circuitry for the life of the board.
One prior art method of applying a layer of primary resist or solder mask to a circuit board surface is to apply the material in liquid form, and then, either allow it to dry or partially cure the material to form a semi-stable layer. There are a number of advantages, however, to applying a photoimageable layer to a circuit board as a dry film rather than as a liquid. In particular, dry films are free of organic solvent and therefore eliminate this hazard from the workplace and eliminate the need for apparatus to protect the immediate work environment and the more general environment from organic solvent emissions.
Typically, such a dry film comprises a cover sheet of support material which is somewhat flexible but which has sufficient rigidity to provide structure to a layer of photoimageable composition which overlies one surface of the cover sheet. The cover sheet may be formed of polyester material, such a polyethylene terephthalate (PET). To protect the photoimageable layer and to enable the dry film to be rolled, it is conventional for the exposed surface of the photoimageable layer to be covered with a removable protective sheet, e.g., a sheet of polyethylene.
The method of use of such a dry film is generally as follows. The protective polyethylene sheet is removed from the photoimageable composition layer immediately prior to application of the dry film to the surface of the printed circuit board. This may be accomplished, for example, using automated apparatus which peels away and rolls up the protective sheet as the dry film is unrolled from a reel. The dry film is applied to the surface of the circuit board with the photoimageable layer in direct contact with the board surface. Then using either heat and mechanical pressure (in the case of roll laminators) or a combination of vacuum, heat, and mechanical pressure (in the case of vacuum laminators), the photoimageable layer is immediately laminated to the surface of the board. The cover sheet remains overlying the photoimageable layer, protecting the photoimageable layer from exposure to oxygen and from handling damage. The cover sheet also permits a pattern (or template) to be laid directly on top of the dry film for contact printing, if contact printing is to be used (as is usually preferred from the standpoint of obtaining optimal image resolution). The dry film is exposed to patterned actinic radiation through the PET cover sheet. At this time, the PET cover sheet is removed, permitting access to the exposed photoimageable layer by developer. Depending upon the composition of the photoimageable layer, the photoimageable layer is developed with organic solvent, aqueous developer, or semi-aqueous developer. The photoimageable layer may either be positive-acting, in which case the exposed portions are removed by developer, or negative-acting, in which case the unexposed portions are removed by developer. Most photoimageable layers for preparing primary imaging photoresists and solder masks are negative-acting. Subsequent to development, primary resists, in particular, are subjected to either electroplating or etching, as previously described, to form the circuit traces after which the remaining photoresist is stripped away with organic solvent, aqueous stripper, or semi-aqueous stripper. Whereas, in the case of solder masks which remain on the board permanently, most photoimageable composition layers require some cure subsequent to development to render the layer hard and permanent so as to serve as a solder mask. Depending upon the composition of the photoimageable layer, curing may be effected with heat and/or UV light.
Printed circuit boards almost invariably have uneven surfaces which present difficulties for dry film application. During solder mask application, in particular, such unevenness is usually attributed to the circuitry traces which are raised or elevated over the surface of the board of electrically non-conducting material. It is therefore desirable that any dry film solder mask applied to the board be able to conform around the upstanding circuitry traces to minimize the risk of defects, such as short circuits. On the other hand, during primary resist application,

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