A process and system for making a laminated surface covering and the surface covering itself are described. The covering includes several layers bonded to each other. The system performs the process. One example of the process includes passing a first material across a first conveyor, passing a second material across a second conveyor, passing a bonding material across a third conveyor, contacting the first material and the second material to the bonding material, and heating at least one of the first material and the second material. The process also includes introducing the first material, the second material, and the bonding material into a pressure zone such that the bonding material is introduced between a bottom surface of the first material and a top surface of the second material. The process applies pressure to bond the first material and second material together via the bonding material to produce a laminated material.

A color sampling display product is provided that includes a radiation-curable water-based coating composition applied to a substrate, and shows mechanical integrity and aesthetic appeal.

Two-component solventless adhesive compositions for lamination applications and laminated structures, including flexible laminated packaging, comprising at least two substrates, including structures comprising reverse printed ink films and/or metallized films. The adhesive comprises a prepolymer having one or more oligomers with a relatively high molecular weight.

A material that is capable of stopping high-speed projectiles but yet is sufficiently flexible for use in various applications, such as to be used in footwear to protect a person's feet, especially the bottoms thereof is achieved by an enhanced ballistic material formed from interleaving layers of a ballistic material and layers of a gel matrix material that remains relatively soft and flexible. The ballistic material layer may be high tensile strength synthetic or polymeric fibers that are arranged in a mesh weave. Preferably the gel matrix material is capable of investing the ballistic material, e.g., by having the gel matrix material fill the interstices of the fibers, which may be achieved through the use of heat and/or pressure. Furthermore, the combined material, i.e., the enhanced ballistic material, may be shaped, e.g., by molding.

The invention relates to methods for coating a substrate with at least one monolayer of self-assembling proteins, using stabilized aqueous solutions with self-assembling proteins, and also to substrates obtainable as a result. Methods for stabilizing solutions with self-assembling proteins, and the stabilized solutions obtainable therefrom, are likewise provided by the invention. According to the coating method, at least one monolayer of a self-assembling protein is produced on a substrate by first providing a stabilized aqueous solution which comprises at least one self-assembling protein. To provide the coating solution, protein units aggregated from an aqueous solution of self-assembling proteins are separated off, and addition of a solution of ionic surfactants and/or of a salt-containing and/or alkaline and/or acidic solution to the protein-containing coating solution generates monomers or oligomers of the self-assembling proteins, and stabilizes them, the amount of ionic surfactant added being such that only the surface-active part of each active protein monomer or predominant protein oligomer is enveloped by surfactant particles. A substrate surface is then brought into contact with the stabilized, protein-containing solution, thus producing a protein-containing coating on the substrate. The supernatant solution is removed from the coated substrate and/or the coated substrate is dried.

The invention provides protein adhesives and methods of making and using such adhesives. The protein adhesives contain ground plant meal or an isolated polypeptide composition obtained from plant biomass.

A method is disclosed of applying a mica paper around an electrical conductor, the process including attaching the tape comprising the mica paper to the conductor at an attachment point on the conductor; winding the tape around the conductor surface until the tape has been wound to a point that is at least 25 percent of the conductor circumference from the attachment point and then initiating a continuous removal of the support layer from the tape, starting at the attachment point; the mica paper remaining in contact with the surface of the conductor; and continuing to wind the tape around the conductor while simultaneously removing the support layer at a removal point until a desired amount of conductor surface is completely covered with at least one layer of the mica paper, with the proviso that the removal point is maintained at least 25 percent of the conductor circumference behind the winding point until the desired amount of conductor surface is completely covered. A tape is also disclosed of mica paper and a support layer, wherein the mica paper; wherein the initial elongation of the support layer is equal to or less than the initial elongation of the mica paper; and wherein the support layer is demountably attached to the mica paper such that when a delamination force of 10 N/10 mm or less is imposed on the support layer it can be separated from the mica paper.

A fluid handling component for a vacuum chamber of a semiconductor substrate processing apparatus is provided. The fluid handling component comprises interior fluid wetted surfaces and an atomic layer deposition (ALD) or molecular layer deposition (MLD) barrier coating on the interior fluid wetted surfaces wherein the fluid wetted surfaces which include the ALD or MLD barrier coating are configured to be contacted by a process gas and/or fluid during a semiconductor substrate processing process wherein the ALD or MLD barrier coating protects the underlying fluid wetted surfaces from erosion and/or corrosion.

An antimicrobial coating system and method are described. In some embodiments, a system may include a composition. The composition may include one or more bridged polycyclic compounds. At least one of the bridged polycyclic compounds may include at least two cyclic groups, and at least two of the cyclic groups may include quaternary ammonium moieties. In some embodiments, a method may include applying an antimicrobial coating to an oral surface, a surface of a construction substrate, a surface of a marine substrate, a surface of a medical device, or a surface of a personal care device. The protective coating may be antimicrobial. A protective coating may include antimicrobial bridged polycyclic compounds. Bridged polycyclic compounds may include quaternary ammonium compounds. Bridged polycyclic compounds based coating systems may impart self-cleaning properties to a surface (e.g., a tooth surface).

The present invention provides a multilayer heat shrinkable film incorporating an oxygen barrier material and layer containing a styrene polymer or blend of styrene polymers, where the shrinkage of the film in at least one of MD, TD is at least 30% at 90 C. The invention is further directed to a method of manufacturing a bag from said multilayer heat shrinkable film.