A material deposition device for decorating an object. The device has a housing as a structural framework, an object holder, and a container releasably coupled to the housing. The housing has an object support for supporting the object to be decorated. The container creates a volumetric enclosure with the housing. The device is configured to deposit decoration materials onto the object.

This application is directed to a device comprising a covering attached to the device. A process of making a device with a specific covering attached is also disclosed. The application further discloses a method for the treatment of perforations, fistulas, ruptures, dehiscence and aneurisms in luminal vessels and organs of a subject.

This application is directed to a device comprising a covering attached to the device. A process of making a device with a specific covering attached is also disclosed. The application further discloses a method for the treatment of perforations, fistulas, ruptures, dehiscence and aneurisms in luminal vessels and organs of a subject.

A process for the large-scale manufacturing vertically standing hybrid nanometer scale structures of different geometries including fractal architecture of nanostructure within a nano/micro structures made of flexible materials, on a flexible substrate including textiles is disclosed. The structures increase the surface area of the substrate. The structures maybe coated with materials that are sensitive to various physical parameters or chemicals such as but not limited to humidity, pressure, atmospheric pressure, and electromagnetic signals originating from biological or non-biological sources, volatile gases and pH. The increased surface area achieved through the disclosed process is intended to improve the sensitivity of the sensors formed by coating of the structure and substrate with a material which can be used to sense physical parameters and chemicals as listed previously. An embodiment with the structures on a textile substrate coated with a conductive, malleable and bio-compatible sensing material for use as a biopotential measurement electrode is provided.

A process for the large-scale manufacturing vertically standing hybrid nanometer scale structures of different geometries including fractal architecture of nanostructure within a nano/micro structures made of flexible materials, on a flexible substrate including textiles is disclosed. The structures increase the surface area of the substrate. The structures maybe coated with materials that are sensitive to various physical parameters or chemicals such as but not limited to humidity, pressure, atmospheric pressure, and electromagnetic signals originating from biological or non-biological sources, volatile gases and pH. The increased surface area achieved through the disclosed process is intended to improve the sensitivity of the sensors formed by coating of the structure and substrate with a material which can be used to sense physical parameters and chemicals as listed previously. An embodiment with the structures on a textile substrate coated with a conductive, malleable and bio-compatible sensing material for use as a biopotential measurement electrode is provided.

The flocked helical spring includes a spring body, a cationic electrodeposition coating layer disposed on the surface of the spring body, an adhesive layer disposed on the surface of the cationic electrodeposition coating layer, and a flocking layer composed of flocking fillers fixed to the adhesive layer. The surface roughness Rz of the cationic electrodeposition coating layer is 19.6 ?m or greater. The method for producing a flocked helical spring includes a cationic electrodeposition coating process of performing a cationic electrodeposition coating treatment on a spring body to form a film of an electrodeposition coating material on the surface of the spring body; an adhesive coating process of coating an adhesive containing a surface roughening solvent on the surface of the film; a flocking process of bonding flocking fillers to the surface coated with the adhesive; and a baking process of heating the spring body adhered with the flocking fillers.

The flocked helical spring includes a spring body, a cationic electrodeposition coating layer disposed on the surface of the spring body, an adhesive layer disposed on the surface of the cationic electrodeposition coating layer, and a flocking layer composed of flocking fillers fixed to the adhesive layer. The surface roughness Rz of the cationic electrodeposition coating layer is 19.6 ?m or greater. The method for producing a flocked helical spring includes a cationic electrodeposition coating process of performing a cationic electrodeposition coating treatment on a spring body to form a film of an electrodeposition coating material on the surface of the spring body; an adhesive coating process of coating an adhesive containing a surface roughening solvent on the surface of the film; a flocking process of bonding flocking fillers to the surface coated with the adhesive; and a baking process of heating the spring body adhered with the flocking fillers.

A method is provided for fabricating a construction (10) having a functional side (12). The method includes the steps of: supplying a flexible substrate (20); attaching one or more structures (30) to the substrate (20) on a surface or side thereof facing the functional side (12) of the construction (10); and forming one or more features, for example, such as fibrils (39), on at least one of the structures (30), wherein the features have at least one dimension which is at least one of micro-sized or nano-sized.

A method is provided for fabricating a construction (10) having a functional side (12). The method includes the steps of: supplying a flexible substrate (20); attaching one or more structures (30) to the substrate (20) on a surface or side thereof facing the functional side (12) of the construction (10); and forming one or more features, for example, such as fibrils (39), on at least one of the structures (30), wherein the features have at least one dimension which is at least one of micro-sized or nano-sized.

A roofing material including a substrate having a top face and a bottom face. The roofing material further includes a non-asphalt coating applied to the substrate and an asphalt layer covering at least a portion of the top face. The bottom face is asphalt-free, or substantially asphalt-free.