Abstract: The insulated glass unit (IGU) that replicates a historic glass window includes a single simulated divided light glass pane, a low-e glass layer, and spacer grills disposed therebetween. True divided light glass window panes are scanned to obtain surface characteristic data, subsequently used to design a pane that includes slumped areas corresponding to the unique topological characteristics of antique glass, separated by flat areas. The flat surfaces provide for sealing the IGU with the spacer grills, while the optics of the original historic glass are preserved via the slumped areas. A mold of the designed pane is then 3D printed in furan resin sand, and a glass layer is melted over the mold to create a one-piece pane that includes the antique features. Accurate replication of these windows enables historic building renovation with modern insulated windows with less sealing while retaining the original appearance, providing improvements in longevity and efficiency.

Abstract: The insulated glass unit (IGU) that replicates a historic glass window includes a single simulated divided light glass pane, a low-e glass layer, and spacer grills disposed therebetween. True divided light glass window panes are scanned to obtain surface characteristic data, subsequently used to design a pane that includes slumped areas corresponding to the unique topological characteristics of antique glass, separated by flat areas. The flat surfaces provide for sealing the IGU with the spacer grills, while the optics of the original historic glass are preserved via the slumped areas. A mold of the designed pane is then 3D printed in furan resin sand, and a glass layer is melted over the mold to create a one-piece pane that includes the antique features. Accurate replication of these windows enables historic building renovation with modern insulated windows with less sealing while retaining the original appearance, providing improvements in longevity and efficiency.

Abstract: The disclosed method may include (1) deploying a virtual-tracking technology across a plurality of customer-facing platforms, (2) detecting, via one customer-facing platform, a first touchpoint between a browser of a contact related to a buyer-side business and a seller-side business, (3) generating, by way of the virtual-tracking technology, a cookie that is linked to the buyer-side business, (4) dropping the cookie into the browser of the contact during the first touchpoint, (5) detecting, via another customer-facing platform, a second touchpoint between the browser of the contact and the seller-side business based at least in part on the cookie, and then (6) tracing a customer journey that (A) represents the interactions between the buyer-side business and the seller-side business via the contact and (B) accounts for the first touchpoint and the second touchpoint. Various other systems, methods, and computer-readable media are also disclosed.

Abstract: An adaptive controller for controlling the temperature of a body. The adaptive controller of the present invention comprises a temperature measuring device which measures the temperature of the body. A controller which has a controller integral time constant and a controller gain constant is provided for controlling a heating device. An adjustment mechanism is provided which determines the controller integral time constant and the controller gain constant where the controller integral time constant and the controller gain constant are dependent upon the difference between the present temperature of the body and the desired temperature of the body.