Abstract: An energy curable bonding resin composition that prevents corrosion in metallic optical structures including DVDs includes at least one monomer, acrylated epoxidized soya bean oil, and a photoinitiator of among 2,4,6-trimethylbenzoyl-diphenylphosphine oxide (TPO); Phosphine oxide, phenylbis 2,4,6-trimethyl benzoyl; oligo[2-hydroxy-2-methyl-1-[4-(1-methylvinyl)phenyl]propanone]; alpha-hydroxy ketone, difunctional; or combinations thereof.

Abstract: A method for bonding two parts together in accordance with an embodiment of the disclosure can include providing first and second parts, placing a light curable adhesive between the first and second parts, and irradiating the light curable adhesive using a modified fiber optic filament disposed between the first and second parts.

Abstract: The present invention relates to thiol-ene curing compositions, which cure upon exposure to ultraviolet (UV) light and/or heat. The compositions include components having alkenyl (or “ene”) functionality and components having thiol functionality, which undergo thiol-ene curing. The compositions also include a cure system. More specifically, in some embodiments, the curable compositions include a vinyl polymer bearing alkenyl or thiol terminal functional group(s) and a cross-linking agent having the opposing functionality, i.e., thiol cross-linking agents with alkenyl-terminated vinyl polymers and vinyl cross-linking agents with thiol-terminated vinyl polymers. Also provided are methods of making and using the compositions, such as for sealants for in-place gasketing applications.

Abstract: A pre-adhesive composition is described comprising an acid- and epoxy-functional (meth)acryloyl copolymer, which when crosslinked using an ionic photoacid generator (PAG) provides a pressure-sensitive adhesive and pressure-sensitive adhesive articles having desirable properties.

Abstract: For simpler production of a waterproof, decorated wall, ceiling or floor panel with improved quality, the invention proposes a process involving the following steps: provision of a panel-shaped carrier and a non-woven fabric, application of an adhesive to one surface of the carrier or to a surface of the non-woven fabric, lamination of the non-woven fabric by means of the applied adhesive to the surface of the carrier, impregnation of the non-woven fabric with a liquid means, hardening of the impregnating agent, application of a sealing layer as a liquid composition and hardening of the sealing layer and/or application of a top layer as a liquid composition and hardening of the top layer.

Abstract: The invention relates to a method for adhesively bonding a magnet onto the surface or into a slot of a rotor or stator of an electric motor or a generator, wherein i) the surface or surfaces to be glued of the magnet, rotor or stator are pre-coated with an adhesive that is not liquid at 22° C. and that does not cure without an activation step, iii) the magnet is brought into contact with the rotor or stator at the adhesive location, and iv) the adhesive is activated by heating or by high-energy radiation so that it cures, characterized in that the adhesive comprises a) at least one reactive epoxide prepolymer, b) at least one latent hardener for epoxies, and c) one or more elastomers. The adhesive preferably comprises a blowing agent. The invention further relates to a corresponding pre-coated magnet.

Abstract: Disclosed is an automatic bonding system for an LCD device. The automatic bonding system includes a bonding unit configured to perform a process of bonding a first substrate to a second substrate, a first substrate supply unit configured to include an inverting arm and supply the first substrate to the bonding unit, a second substrate supply unit configured to include an adhesive resin coating unit and supply the second substrate to the bonding unit, a pre-hardening unit configured to perform a process of pre-hardening an adhesive resin that adheres the first and second substrates, and a hardening unit configured to perform a process of hardening the adhesive resin that adheres the first and second substrates. A gap between the first and second substrates bonded to each other by the bonding unit is a bonding gap controlled by a gap variable control stage.

Abstract: An embodiment of manufacturing method of a flat-panel display device having a display panel and a transparent protector sheet; comprises: setting a bi-directionally Y-shape branched line pattern within a rectangular to-be-bonded area, which is formed of two Y-shaped intersections of a center line and angle bisector lines of the corners, of the to-be-bonded area; and applying adhesive resin onto the protector sheet or onto the display panel by forming circular or ellipsoidal dot patterns of applied adhesive resin so that: the dot patterns are arranged on the center-line segment and on the branch lines or their vicinities; and the dot patterns are arranged in symmetry with respect to the center line and to its perpendicular bisector.

Abstract: An adhesive may be formulated with a functional component that reacts in the presence of ultraviolet light with a neighboring functional component to form a nonreversible bond therebetween. The functional component may include at least one —C?C— functional group that is able to undergo dimerization with a neighboring component. A method for making the adhesive includes covalently bonding the functional component to a support polymer, wherein the functional component may be covalently bonded to the support polymer by a linking molecule. A kit containing the adhesive and an ultraviolet light source is also provided.

Abstract: Roll-to-roll processes for manufacturing touch sensors using a sheet of patterned photoresist film are disclosed. The photoresist film can include a sheet of photoresist material, such as DFR, that has been patterned by removing portions of the photoresist film using a die or laser cutting technique. In some examples, the photoresist film can be patterned such that the patterned photoresist film can be laminated to a base film and used as an etching mask or a photoresist layer in a roll-to-roll manufacturing process. In this way, the patterned photoresist film can be used in place of conventional photoresist films in roll-to-roll processes, thereby obviating the need for subsequent exposure and development operations that would otherwise be performed when using conventional photoresist films. As a result, the chance that a defect is introduced into the touch sensors is reduced by reducing the number of operations performed in the roll-to-roll process.

Abstract: A method and apparatus for forming a vehicle window assembly utilizes one or more induction heating devices to adhesively bond an item of hardware to a glass substrate, which substrate is then adapted to fill an opening in a vehicle body. Preferably, the induction heating device(s) and one or more assembly aids are components of an assembly fixture which allows for automated or semi-automated production of such vehicle window assemblies.

Abstract: The present invention relates to a membrane filter comprising a plurality of pores of substantially the same size. The membrane filter may be supported by at least one support (e.g. in the form of a support grid) and is able to handle a large flux and pressure in use. The invention also relates to a method of fabrication of such a filter membrane using a solvable mold.

Abstract: The present disclosure provides a blocking device, which includes a blocking plat having a blocking pattern and transparent areas and an electromagnetic suction unit for sucking the blocking plate. In the embodiment, with the electromagnetic suction unit sucking the blocking plate, the requirements about the smoothness and cleanness of the surface of the blocking plate are decreased to reduce the manufacturing cost and maintaining cost of the sealant curing machine. Additionally, the blocking plate is more stably sucked.

Abstract: The present invention relates to the field of 3D display technology and provides a polarizer, manufacturing method thereof, and a 3D display device. According to the present invention, a transition layer is provided between an alignment layer and a supporting layer, and there is excellent wettability between the transition layer and the supporting layer as well as the alignment layer. The polarizer comprises a polarizing layer for producing linearly polarized light, a supporting layer located at one side of the polarizing layer, a transition layer arranged on one side of the supporting layer away from the polarizing layer, an alignment layer arranged on one side of the transition layer away from the polarizing layer, and an optical rotation layer arranged on one side of the alignment layer away from the polarizing layer.

Abstract: Light-emitting devices that include a scattering element of arbitrary shape and processes for fabrication thereof are described. In one aspect a method for forming a light-emitting device includes providing a light-emitting element (LEE) on a base surface of a base substrate; coupling a first optical element with the base surface of the base substrate, where the first optical element has a first surface facing the LEE and a second surface opposing the first surface; disposing the first optical element in a curable or settable fluid so that the fluid conforms to the second surface; and curing or setting the fluid to form a second optical element including a molded transparent layer adjacent the second surface of the first optical element.

Abstract: A method includes providing a touch panel interposer, where providing the touch panel interposer comprises providing a touch panel device, applying a first adhesive layer to a cover side of the touch panel device, and applying a second adhesive layer to a display side of the touch panel device. The method further includes providing a touch panel display, where providing the touch panel display comprises applying a cover to the first adhesive layer, and applying a display panel to the second adhesive layer.

Abstract: A method is disclosed for producing an electronic component including at least two functional layers. One of the functional layers has channels, open towards the other functional layer, which run inwards from one edge of the functional layer. Further, an adhesive which contacts the adjacent functional layers is located in at least one of the channels, and a hardening of the adhesive is effected by introducing UV radiation via the channels. Furthermore an electronic component is also disclosed, including at least two adjacent functional layers adhesively bonded together in sandwich-like fashion, wherein at least one of the functional layers has channels which extend inwards from at least one edge of the functional layer and an adhesive hardened by UV radiation is arranged in the channels. A detector element of a radiation detector including such an electronic component and a radiation detector having such a detector element are also disclosed.

Abstract: Provided is a method of manufacturing a translucent rigid substrate laminate, which method can improve position precision while increasing production efficiency. Further provided is a translucent rigid substrate bonding apparatus that contributes to improvement of the position precision while increasing production efficiency of a plate-shaped product. In the method of manufacturing a translucent rigid substrate laminate and the translucent rigid substrate bonding apparatus according to the present invention, when translucent rigid substrates are bonded in a predetermined positional relationship by interposing a photo-curable fixing agent including (A) polyfunctional (meth)acrylate, (B) monofunctional (meth)acrylate and (C) a photopolymerization initiator therebetween, only the fixing agent present in outer peripheral portions of both translucent rigid substrates is cured for provisional fastening.

Abstract: The present invention provides an adhesive layer for an electrical connection. The adhesive layer includes a base resin; an ionic optical-curing agent; an optical curing accelerant; and a conductive particle having a size of several to several tens nanometers, wherein the adhesive layer is cured by a UV light, and the UV light is diffused by the optical curing accelerant.

Abstract: A process for the manufacturing of a decorative surface element, which element comprises a base layer and a decorative upper surface. A radiation curing lacquer is printed in a predetermined pattern as an uppermost layer on the decorative upper surface. The radiation curing lacquer covers only parts of the decorative upper surface whereby the lacquer is exposed to radiation whereby it cures. A surface structure is hereby achieved.

Abstract: A liquid crystal lens panel includes a first substrate including a lens area, a non-lens area disposed adjacent to the lens area, and a cutting area disposed adjacent to the non-lens area and including a liquid crystal driving part, a second substrate disposed opposite to the first substrate, and a liquid crystal layer interposed between the first substrate and the second substrate, where the liquid crystal driving part applies a liquid crystal driving voltage to the liquid crystal layer through the non-lens area, and liquid crystal molecules of the liquid crystal layer are driven substantially in a vertical direction by the liquid crystal driving voltage.

Abstract: The first aspect of the instant claimed invention is a method of formulating radiation curable Supercoatings for application to an optical fiber used in a telecommunications network. A Multi-layer Film Drawdown Method useful in the Method of formulating radiation curable Supercoatings is also described and claimed. Single mode Optical fibers coated with specific radiation curable Supercoatings are also described and claimed.

Abstract: A production method of three-dimensional pattern is disclosed. First, an adhesive layer is applied on a three-dimensional workpiece. Next, a film is vacuum adsorbed on the adhesive layer so that the film is impressed onto the adhesive layer to form the three-dimensional pattern on the adhesive layer. Finally, the adhesive layer is cured by implementing a plurality of heat treatments thereon. A workpiece of three-dimensional pattern and a production device of three-dimensional pattern are also disclosed.

Abstract: The first aspect of the instant claimed invention is a method of formulating radiation curable Supercoatings for application to an optical fiber used in a telecommunications network. A Multi-layer Film Drawdown Method useful in the Method of formulating radiation curable Supercoatings is also described and claimed. Single mode Optical fibers coated with specific radiation curable Supercoatings are also described and claimed.

Abstract: One possible embodiment of the invention could be a methodology of preventing an existing crack or break in the vehicle windshield from becoming larger comprising of the steps, providing a laminate with a UV light-permeable barrier film having least one side to which UV light curable adhesive is applied to it, a peel-able cover reversibly applied over the adhesive; providing a windshield with at least a small crack or chip in its surface; removing the peel-able cover from the adhesive; applying the barrier film to the windshield in a manner to cover the crack or chip so that the adhesive comes in contact with the windshield; and transmitting UV light through the film to the adhesive to cure it into a rigid substrate connection between the barrier film and the windshield that resists various forces acting upon the windshield that would otherwise increase the size of crack or chip.

Abstract: Disclosed are a method for manufacturing a positive temperature coefficient (PTC) device and a system for preventing overheating of a planar heater using the same. The manufacturing of the positive temperature coefficient (PTC) device is performed by mixing one or more polymer resins selected from ethylene butyl acrylate copolymers, ethylene vinyl acetate copolymers and polyethylene oxide, carbon black and an additive to prepare a compounding composition, adhering an electrode to both surfaces of the compounding composition, compressing the resulting electrode structure into a sheet, and irradiating electron beams to the sheet to perform cross-linking. Also, disclosed is a planar heater overheating prevention sensor cable obtained by connecting a plurality of PTC devices in series and adhering the devices to the surface of a planar heater by a predetermined distance.

Abstract: An adhesive composition according to the present invention contains a polymerizable group-containing siloxane compound, a polymerization initiator and an ultraviolet-absorbing blowing agent. This adhesive composition enables quick bonding of substrates etc. by light irradiation or by heating such that the bonded substrates can secure adhesion and heat resistance to withstand grinding etc. and, when no longer needed to be bonded, can be easily separated from each other by ultraviolet light irradiation and is thus suitable for use as an adhesive composition for manufacturing of semiconductor devices (particularly for manufacturing of semiconductor devices with through-silicon vias).

Abstract: A method of forming an integrated circuit includes providing a wafer, and a tape adhered to the wafer, wherein the tape has a main surface perpendicular to a first direction. The tape is exposed to a light to cause the tape to lose adhesion. In the step of exposing the tape, the wafer and the tape are rotated, and/or the light is tilt projected onto the tape, wherein a main projecting direction of the light and the first direction form a tilt angle greater than zero degrees and less than 90 degrees.

Abstract: Disclosed is a urethane (meth)acrylate oligomer which is obtained by reacting at least one polyoxyalkylene polyol (A), at least one monool (B1) soluble in the component (A) and/or at least one silane coupling agent (B2) reactive with an isocyanate group, at least one polyisocyanate (C) and at least one hydroxylated mono (meth)acrylate compound (D) at a ratio at which the equivalent weights of hydroxy groups, active hydrogen groups and isocyanate groups in the respective components satisfy the following formulae (1)-(3). The urethane (meth)acrylate oligomer does not substantially contain an unreacted isocyanate group. B(active hydrogen)+D(OH)=C(NCO)?A(OH) (1) 1.05?C(NCO)/A(OH)?2 (2) {C(NCO)?2A(OH)+2m}×0.35?D(OH)?{C(NCO)?2A(OH)+2m}×0.

Abstract: A multi-layer body (1, 21) is described, having a carrier film (7), a release layer (8), an embossed hologram layer (9) and a vapour-deposited reflection layer (10), a UV-activatable adhesive layer (4) with at least one partially activated UV adhesive-layer zone (5, 6) and a lower layer, wherein the cured adhesive regions (5) connect the lower layer and parts of the embossed hologram layer to one another inseparably, the lower layer being a transparent polycarbonate film (2), while the cured adhesive region (5) is arranged on the periphery of the uncured adhesive region (6) of the respective adhesive-layer zone (4) and surrounds it in a frame-like manner.

Abstract: A method of forming an elastomeric sheet adhesive bond between mating surfaces of an electrode and a backing member to accommodate stresses generated during temperature cycling due to mismatch in coefficients of thermal expansion. The elastomeric sheet comprises a thermally conductive silicone adhesive able to withstand a high shear strain of ?300% in a temperature range of room temperature to 300° C. such as heat curable high molecular weight dimethyl silicone with fillers. Installation can be manually, manually with installation tooling, or with automated machinery.

Abstract: A method of producing a flexible laminate and a flexible laminate produced by the method are provided. The method involves laminating flexible substrates with a urethane adhesive and allowing the urethane adhesive to cure. The urethane adhesive comprises at least one polyisocyanate, at least one polyfunctional curative, at least one metal based catalyst and a catalyst blocking agent. The catalyst blocking agent allows for improved control of the curing rate of the urethane adhesive in the flexible laminate. The curing rate of the urethane adhesive can be controlled with heat or actinic radiation or both. The method allows for faster and more economical production of flexible laminates.

Abstract: The present invention relates to a method for the continuous inline production of coated polymeric substrates or laminates and also to an apparatus for implementing this method.

Abstract: An apparatus and method for controlling radial runout between stacked disk portions (14, 18) and providing a cylindrical pin (20) having at least two diameters (22, 24). The pin is dimensioned and configured to permit the disk portions, which have different center hole dimensions, to be indexed such that a center hole of each disk portion is received by a separate diameter of the pin. The disk portions are maintained in spatial relationship as provided by the pin by spot curing a portion of the adhesive.

Abstract: A polymer laminate is fabricated by laying down layers of an ultra-high molecular weight polymer material on top of each other, and fusing the layers to each other by cross-linking molecular chains of adjoining layers.

Abstract: An image reading device and a method for manufacturing the same are provided, where the image reading device is capable of being assembled more efficiently. The image reading device includes: an optical part, extending long in a direction; a case, having an accommodating portion for accommodating the optical part; and a light receiving component, accommodated in the case. The optical part is fixed in the accommodating portion through a first adhesive and a second adhesive with hardening time longer than that of the first adhesive.

Abstract: A bonding method of bonding two base members together through a bonding film is provided. The bonding method is a method for forming a bonded body in which a first base member and a second base member are bonded together through the bonding film. The bonding method includes: applying a liquid material containing a silicone material composed of silicone compounds onto a surface of at least one of the first and second base members to form a liquid coating on the surface; drying the liquid coating so that it is transformed into the bonding film on the surface of the at least one of the first and second base members; and applying energy to the bonding film so that a bonding property is developed in the vicinity of a surface thereof, to thereby bond the first and second base members together through the bonding film.

Abstract: A process for protecting the external face of an electro-optical device, the external face comprising at least one optical film adhesively bonded to a transparent substrate and set back therefrom, comprises encapsulating the optical element between the substrate and a transparent cover that is substantially the same size as the substrate. The process comprises adhesive bonding of the cover, the adhesive bonding being achieved by depositing uncured adhesive in two steps, namely a first step that is used first to take up the step difference between the substrate and the optical element, and a second step that is used to adhesively bond the protective cover. Smaller respective thicknesses of adhesive shrink in each step and thus, in the end, the total shrinkage is limited and the quality of the product is improved.

Abstract: A method of fabricating an LCD device is discussed. The method according to an embodiment includes combining a first substrate having thin film transistors with a second substrate having black matrices and color filters using a sealant. Also, the method includes: forming an absorbent layer which is positioned to overlap with an edge of the sealant and burned by a laser; curing the sealant partially covered with the absorbent layer by irradiating UV light; burning the absorbent layer using a laser beam; and cutting the sealant through the burnt absorbent layer and the second substrate opposite to the absorbent layer using a scriber.

Abstract: Methods for controlling deformation of laminated display assemblies are described. The laminated display assemblies can include flexible layers. In some embodiments, the flexible layers are sensor layers. Methods involving the use of a thermal press and ultra violet (UV) curing procedure are described. In one embodiment, a thermal press method can be performed by placing a laminated display assembly including the flexible substrate, an ink layer, an adhesive, and a cover on a temperature controlled fixture. A mechanical press can apply pressure to the top of the laminated display assembly. The mechanical press can remove any planar deformity of the flexible layer and can redistribute portions of the adhesive. Following the mechanical pressing, the laminated display assembly can be exposed to UV light to cure the adhesive and thereby fix in place the planar state of the laminated display assembly.

Abstract: According to a method of manufacturing an image display device of the present invention, a photo-curable resin composition in a liquid state is applied to a surface of a light-transmitting cover member including a light-shielding layer or a surface of the image display member to a thickness greater than that of the light-shielding layer. Then, in this state, the photo-curable resin composition is irradiated with a UV ray to be pre-cured, thereby forming a pre-cured resin layer. Next, the image display member and the light-transmitting cover member are stacked via the pre-cured resin layer and thereafter, the pre-cured resin layer is irradiated with a UV ray to be completely cured, thereby forming a light-transmitting cured resin layer.

Abstract: Methods and devices for using liquid optically clear adhesives (LOCAs) are described. A method for detecting uncured LOCA between a first substrate and a second substrate is described. In addition, an improved method for curing a laminated stack up having LOCA between a first substrate and a second substrate is described. The method includes a pre-curing method involving variable exposure of the LOCA. In addition, an improved light emitting diode (LED) unit assembly for exposing a laminated stack up to ultraviolet (UV) light during a pre-curing process is described. A method for testing the LED unit assembly prior to a pre-curing process is described.

Abstract: The present invention relates to urethane(meth)acrylate resins obtained from the reaction, in a first step, of at least one polyisocyanate (I) with at least one compound (II) containing at least two reactive groups capable to react with isocyanate groups and at least one (meth)acrylate (III) containing essentially one reactive group capable to react with isocyanate groups, and, in a subsequent step, reacting the product obtained from the first step with at least one polyisocyanate (IV) different from the poly-isocyanate (I) used in the first step, and their use for making radiation cured pressure sensitive adhesives.

Abstract: Provided is a method of producing a circuit board that can stably provide normal circuit boards by preventing the solder detachment and the generation of needle-like crystals during the formation of solder bumps. The method of producing a circuit board includes steps of forming an adhesive layer by applying an adhesiveness-imparting compound to the surface of a terminal of the circuit board; attaching solder particles onto the adhesive layer; applying an activator that includes a hydrohalic acid salt of an organic base to the solder particles and fixing the solder particles by heating the circuit board to which the solder particles have been attached at a temperature equal to or lower than the melting point of the solder; applying a flux to the circuit board to which the solder particles have been fixed; and melting the solder particles by heating the circuit board.

Abstract: An installation system for mounting stationary objects, such as towel holders, shelves, lights, or similar furnishing items, on an installation surface, such as a wall or a ceiling, in particular in rooms equipped with tiles, marble slabs, or similar wall coverings, includes one or more fastening elements, a lighting device, and/or an adhering and connecting agent, wherein the adhering and connecting agent is a light-curing adhesive. The one or more fastening elements can be fastened by introducing an adhering and connecting agent into an adhesive space formed by the installation surface and components of the fastening element. The fastening element has at least one at least partially transparent component for irradiating the adhering and connecting agent.

Abstract: According to one embodiment, a method of making a roofing membrane is provided. According to the method, an ethylene propylene diene monomer rubber (EPDM) material sheet is provided and a thermoplastic polyolefin (TPO) material sheet is extruded onto the EPDM material sheet. The EPDM material sheet and TPO material sheet are then pressed together via one or more rollers. The EPDM material is uncured and has a thickness of between about 50 mils and 70 mils. The extruded TPO sheet has a temperature of at least 150 degrees Celsius and a thickness of between about 15 mils and 35 mils. The heat of the TPO material sheet causes a top portion of the EPDM material sheet to cure such that crosslinking of the TPO and EPDM material sheets occurs at an interface of the sheets to bond the sheets together.

Abstract: A method of making a wound dressing comprising the steps of: providing an apertured substrate layer; coating the substrate layer with a fluid silicone prepolymer composition; thermally partially curing said silicone prepolymer composition to form a partially cured silicone coating on the substrate; laminating the coated substrate layer to a base layer to form a laminate having said partially cured silicone coating in contact with a surface of the base layer; followed by exposing the laminate to ionizing radiation, to further cure the partially cured silicone coating and to bond the silicone coating to said surface of the base layer. The radiation cure results in strong bonding between the siliconized substrate and incompatible base layers such as polyurethane foams. Also provided are wound dressings obtainable by the process of the invention.

Abstract: An electronic device may be provided with electronic device structures such as housing structures and structures associated with electrical components. The electronic device structures may be attached to each other using ultraviolet and visible light curable adhesive. A layer of adhesive may be interposed between electronic device structures. A light source may generate ultraviolet light. The structures may include an ultraviolet-light-transparent structure through which the ultraviolet light passes to illuminate and cure the adhesive. The ultraviolet-light-transparent structure may form one of multiple shots of injection molded plastic in a device structure, may be formed using a plastic that is opaque at visible wavelengths, or may have a coating such as a metal coating to help reflect ultraviolet radiation onto the adhesive. Perforations in the coating may be used to pass ultraviolet radiation to the adhesive.

Abstract: Provided is a process for producing a composite device comprising a light shielding first member and a light transmissive second member, a first surface of the light shielding first member and a second surface of the light transmissive second member being bonded to each other through intermediation of an ultraviolet curing adhesive, the second surface being larger than the first surface, the process including irradiating a region of the second surface to which region the first surface is not bonded with an ultraviolet ray, wherein a reflective member having a reflective surface with an inclination with respect to the second surface onto the light transmissive second member so that the ultraviolet ray that has transmitted through the second surface is reflected toward the ultraviolet curing adhesive between the second surface and the first surface.

Abstract: A method of determining bonding agent coverage in a joint between a first substrate (10) and a second substrate (12), including: dispersing a marker material (18) throughout a bonding agent (16); melting the bonding agent (16) but not the marker material; solidifying the melted bonding agent (16) to form an actual bond (24) in a joint between the first substrate (10) and the second substrate (12); detecting the marker material (18) in the joint through at least one of the substrates to ascertain an actual bond (24); and comparing the actual bond (24) to an expected bond (28) for the joint to determine the bonding agent coverage.