Patent Document

FIELD OF THE INVENTION 
     The present invention relates generally to an electromagnetic energy spot curing system, and more particularly to an integration of inert gas to an UV curing source unit to overcome oxygen inhibition. 
     BACKGROUND OF THE INVENTION 
     Ultraviolet (UV) lamps are well-known in the art to cure certain curable compounds such as adhesives and the like. UV spot curing systems are used in various applications including the curing of industrial sealants for potting electronics, bonding plastics in the medical industry and the curing of dental filling materials, disk drive industry amongst other applications. Generally, the presence of air would reduce curing of the adhesive. During photopolymerization, as you radiate UV energy or light, the free radicals that are formed during curing are destroyed by reaction with oxygen from the air. Therefore, it is desired to integrate an inert gas with an UV irradiance onto the adhesive surface during the curing cycle. This integration of the inert gas overcomes oxygen inhibition associated with photopolymerization of acrylate/methacrylate products. 
     UV curing devices for curing adhesive between two layers of an information carrier, used particularly for disk drive industry, are disclosed in U.S. Pat. Nos. 6,361,846; 6,170,172; 6,148,542 and 6,108,933. The devices described in these patents is a device that cures the adhesive by means of UV radiation in an inert-gas atmosphere. These devices include a curing chamber or enclosure filled with inert gas that isolates the adhesive from the atmospheric oxygen. However, such devices do not have the ability to accurately focus the light to a confined area or location. Also, the reactive material is required to be enclosed in a chamber. Finally, the curing is performed at a low irradiation intensity making the curing process slow and inefficient. 
     Therefore, a need exists to provide a spot curing system which overcomes the deficiencies of the prior art. 
     SUMMARY OF THE INVENTION 
     The present invention provides an electromagnetic energy spot curing method and system which produces an extremely high UV irradiance resulting in a faster and more efficient process. The system is capable of accurately focusing the light to a specific area needed to be cured. Moreover, the material to be cured need not be enclosed in a chamber. Furthermore, the spot curing system of the present invention is portable and can be integrated into a continuous throughput production system. 
     The system includes a curing unit having a radiation source positioned to irradiate a work piece with radiation energy. A light guide is positioned opposite the curing unit having a light entrance end for receiving the radiation energy and a light exit end for dispersing the radiation energy on the work piece. The system also includes a tube positioned generally parallel to the light guide having a first end for receiving an inert gas and a second end for dispersing the inert gas on the work piece. Moreover, the system includes a fixture where the light exit end of the light guide is integrated with the second end of the inert gas to disperse the gas and the radiation energy simultaneously onto the work piece thereby curing an adhesive surface on the work piece. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a top view of UV spot cure system in accordance with the subject of the invention. 
         FIG. 2  is a top and front view of the light guide with inert gas attachment of the system. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The subject invention relates to an electromagnetic energy spot curing system which utilizes a source of radiation found in the electromagnetic spectrum (e.g., ultraviolet (UV); infrared). To describe the invention and illustrate its functioning, reference is made herein to the use of a UV lamp. It is to be understood that the UV lamp can be interchanged with other sources of electromagnetic energy. In addition, the electromagnetic energy source may provide electromagnetic energy of varying intensities and/or of varying wavelengths (e.g., various types of radiation). 
     With reference to  FIGS. 1 and 2 , an electromagnetic energy spot curing system is generally shown and designated therein with the reference numeral  10 . 
     The system  10  includes a UV lamp  11 , including a light source  12  and an elliptic reflector  13 . The light source  12  is preferably connected to the elliptic reflector  13  so that the energy emanated from the UV lamp  11  is focused at a precise desired location which is an entrance to a light guide  20 . 
     The UV lamp  11  may preferably be a conventional straight mercury arc lamp, metal halide mercury lamp, a xenon-metal halide lamp or any other suitable radiation emitting lamp known in the art. The lamp  11  is controlled by a ballast  14 . Ballast  14  is a known electrical device or chip used in fluorescent and HID fixtures for strating and regulating fluorescent and high intensity discharge lamps. Ballast  14  acts as a power regulating source providing sufficient increasing power for the lamp  11  and further controlling the level of power supplied to the lamp  11 . 
     The light  20  is preferably positioned within a curing unit. The light guide  20  may be glass, optical fiber or any other suitable light transmissive material known in the art, and is preferably of the liquid-filled type. The light guide  20  includes a light entrance surface  20   a  at one end which projects towards the lamp  11  and a light exit/output surface  20   b  at the other end which may be directed to a work site or target which contains adhesive material to be light cured. The light exit surface  20   b  of the light guide  20  terminates at a single fixture  21  from which the UV radiance is dispersed. 
     The light guide  20  is supported by a light guide tube receptacle  22 . The light guide tube  22  is suitably mounted on a light guiding mounting plate  23 . Light guide tube  22  has an opening for supportable receipt of the light guide  20  therein. As will be described in more detail below, the light guide  20  acts to at least partially collimate the UV beam E, and the beam is emitted from the light guide  20  via the light exit surface  20   b . As is readily apparent, the light exit surface  20   b  is directed to the work site or target which contains adhesive material to be light cured. 
     Furthermore, a shutter/stop mechanism including a shutter  24  which is generally planar and made of aluminum is affixed to the light guide mounting plate  23 . The shutter  24  is positioned generally parallel to the lamp  11  to selectively control UV energy emanating from the system. The shutter  24  also has an opening  24   a  of generally circular configuration located at the center of the shutter. Preferably the shutter  24  is located to selectively control UV energy entering the light guide  20  through the light entrance surface  20   a . The opening and closing of the shutter  24  is described herein. The shutter  24  is movable from a first position, the closed position, wherein a solid portion of the shutter  24  covers the light entrance surface  20   a  of the light guide  20  to a second position, the opened position, wherein the shutter opening  24   a  is in registry with the light entrance surface  20   a  thereby allowing light to pass through the opening  24   a  to the light entrance surface  20   a  of the light guide  20 . As the UV light beam passes within the light guide  20 , it is emitted from the light guide  20  via the light exit surface  20   b  to the worksite containing adhesive material to be cured. 
     The mechanism for the movement of the shutter  24  is controlled by a solenoid (not shown). Upon appropriate signals the solenoid is activated which in turn moves the shutter  24  from the first position to the second position as discussed above. A timer  15  preferably controls the time period for shutter  24  to remain in the closed and open positions thereby controlling the exposure time of the radiation. The opening and closing of the shutter  24  may be synchronized with a shut off valve  16  in order to preferably synchronize the UV irradiance with a flow of inert gas as will be described in detail below. 
     The system additionally includes a tube  26  used to feed and disperse inert gas. Preference is given to argon, but gas such as nitrogen, helium or neon are also suitable. The tube  26  includes one end  26   a  attached to a source from which the inert gas is fed in the tube  26  and an opposing end including a dispersion nozzle  26   b  from which the inert gas is dispersed. The dispersion nozzle  26   b  of the tube  26  is integrated with the light exit surface  20   b  of the light guide  20  into the single fixture  21  and is designed to disperse the inert gas simultaneously with the light output and/or the UV radiance to the adhesive surface of the work piece. 
     The regulator  17  preferably controls the rate of flow of the inert gas received in the tube  26  via shut off valve  16  thereby controlling the amount of gas to be dispensed onto the work piece. The shut off valve  16  is preferably solenoid operated to start and stop the flow or movement of the inert gas. In other words, when solenoid is activated, which in turn either opens the valve  16  to start the flow of inert gas in the tube  26  received from the source or shuts off the valve  16  to stop the flow of inert gas in the tube  26 . Also, the operation of the valve  16  is controlled by the timer  15 . The timer  15  is preferably connected to the valve controlling the time period for valve  16  to remain in open and closed positions, thereby controlling the time period of the flow of the inert gas. 
     In operation, the lamp  11  is activated by the ballast  14  to emanate a focused UV energy beam E through the reflector  13 . This focused UV energy beam falls right on the shutter  24 . The shutter  24  being movable in a second position as discussed above, wherein the shutter opening  24   a  is aligned with the light entrance surface  20   a , which allows the UV energy beam to travel into the light guide tube  22  to pass through the light entrance surface  20   a  into the light guide  20 . As the UV energy beam is originating from the lamp  11  and passed through the light guide  20 , simultaneously, the inert gas provided by a source is fed into the tube  26  which is encountered by the shut-off valve  16 . The shut-off valve  16  as discussed above is opened to pass the flow of the inert gas into the tube  26 . The shut-off valve  16  causes to initiate the flow or movement of the inert gas through the tube  26  upon the UV energy being emitted. In other words, the relative movement of the inert gas is initiated upon opening of the shutter  24 . Both the tube  26  and the light guide  20  terminate at a common fixture  21 . In other words, the light exit end  20   b  of the light guide and the dispersion nozzle  26   b  of the tube  26  integrate into the fixture  21  dispensing both the UV energy and the inert gas  21  from the fixture. Therefore, during the curing cycle, both the focused UV energy E and the inert gas are dispersed simultaneously on to the adhesive surface of the worksite. As a result of this operation, material can be cured with the exposure of radiation energy and the dispersion of inert gas simultaneously in order to expel oxygen which would interfere with the curing process. The irradiance levels for spot systems described in the present invention can easily exceed 20 W/cm 2 , whereas, other systems typically produce no more than a couple of W/cm 2 , (i.e., Fusion system electrodeless lamp system). 
     The devices and the system of the present invention can be used in conjunction with a variety of different photocurable adhesive compositions. For example, UV curable vinyl and (meth)acrylate-containing compositions, which may also be optionally anaerobically curable, may be employed. Such compositions may include urethane-acrylate copolymers and block copolymers such as those disclosed in U.S. Pat. Nos. 3,425,988; 4,295,909; and 4,309,526. Other useful photocurable compositions containing reactive (meth)acrylate components are disclosed in U.S. Pat. Nos. 4,415,604; 4,424,252; and 4,451,523, all to Loctite Corporation. 
     Photoinitiators which are intended to be active primarily in the ultraviolet (UV) region are incorporated along with the curable component, and which upon exposure to sufficient ultraviolet light initiate photopolymerization of the curable component. Such UV compositions can be used as structural adhesives, potting compounds, gap filling compounds, sealing compounds, conformal coatings as well as other applications known to those skilled in the art. 
     In addition to the aforementioned adhesive compositions, UV curable silicone compositions are also contemplated as being useful with the present invention. Such compositions contain a curable silicone component and a UV photoinitiator component. Additionally, cyanoacrylate adhesives designed to cure upon exposure to photoirradiation may also be employed. 
     Examples of commercially available UV curing compositions include Loctite product numbers Adhesive 352, 3321, 3491, 3525 and 3201. 
     Having described the preferred embodiments herein, it should be further appreciated that various modifications may be made thereto without departing from the contemplated scope of the invention. As such, the preferred embodiments described herein are intended in an illustrative rather than a limiting sense. The true scope of the invention is set forth in the claims appended hereto.

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