Bonding glass is challenging due to the brittle properties of the material. At the same time, it is interesting for architectural applications and design, especially when carried out transparently. Thus, the adhesive joint and the substrate material appear as a uniform surface without disturbance. A variety of transparent adhesives is available for this purpose, whereby epoxy resins and polyurethanes fulfill the highest structural requirements due to their crosslinking properties. In addition, the curing of both adhesive systems can be accelerated by heat so that short cycle times, which are economically necessary for the production of bonded joints, are achieved. However, in conventional oven heating the entire prefabricated construction element, often several meters long, has to be placed in the oven. This results in long curing cycles, high-energy consumption and high costs, which makes the production extremely unprofitable from an economic and environmental point of view. More effective and targeted heating is achieved by induction or resistance processes, but these methods require activatable components in or on the adhesive joint. Electrically conductive or magnetizable fillers for adhesives are non-transparent and metallic substrates such as brackets or fixings do not exist on glass-glass bondings. Therefore, this study investigated the possibilities of heat generation on little visible metallic inserts, wires and conductive glass coatings. Different adhesives were investigated for their accelerated heat curing and the effects on the glass bond strength were analyzed. The heating properties of possible insert materials and coatings have been evaluated. With the combination of an epoxy resin adhesive and an in-joint heat generation, uniform and fast curing of a highly transparent joint suitable for structural applications could be achieved.