This disclosure describes a composition that includes a bulk diffuser that includes a film having a major surface; the film includes a polymer, and a scattering element. The scattering element includes a silicone bead having a mean particle diameter in a range of 2 micrometers (μm) to 9 μm. The linear density of the film is at least 5.1 W.sub.i*μm, wherein the linear density equals the product of the mass fraction of the silicone bead (W.sub.i) and film thickness in micrometers (μm). This disclosure further describes methods of making the film and the bulk diffuser and methods of using the film including, for example, as a bulk diffuser in a sign box.

Object: Provided is a decorative vapor deposition sheet that can reduce or prevent a defect, such as the breaking of a metal vapor deposition layer or the entire sheet, even when applied to a forming method requiring high temperature or the like. The decorative vapor deposition sheet of an embodiment of the present disclosure is a decorative vapor deposition sheet including a cover resin layer and a metal vapor deposition layer, in which the cover resin layer has a thickness of approximately 50 micrometers or greater, the metal vapor deposition layer exhibits a granular structure, a breaking elongation of the decorative vapor deposition sheet at 20° C. is approximately 120% or greater, and a breaking elongation of the decorative vapor deposition sheet at 160° C. is approximately 350% or greater.

A bottle cap stadium/arena table related to the field of indoor/outdoor furniture. More specifically, a table that mimics a stadium/arena in which sports fans can customize using their own bottle caps. The inventive device includes a table frame with perforated plates that hold decorative bottle caps around the central sporting area that mimics people sitting in the stands; including miniature accessories to depict a particular sporting event (goals, flags). The table, which mimics a miniature stadium/arena, includes a glass tabletop that acts as the table's surface. The table is user customizable to a specific sporting team.

A signage overlay article includes a polymeric substrate having a thickness in a range from 75 to 1000 micrometers, an optically active sign sheeting fixed to the polymeric substrate, and a pressure sensitive adhesive layer adhered to the polymeric substrate. The pressure sensitive adhesive layer has a thickness in a range from 350 to 3000 micrometers.

Disclosed is an acrylic resin composition that has excellent weather resistance and can be stably produced at high temperatures. Specifically, disclosed is an acrylic resin composition including, with respect to 100 parts by mass of an acrylic resin, from 0.1 to 8 parts by mass of a triazine-based UV absorber including 2-(4,6-diphenyl-1,3,5-triazin-2-yl)-5-[2-(2-ethylhexanoyloxy)ethoxy]phenol, wherein the acrylic resin used is an acrylic resin including at least 80 wt % of methyl methacrylate as a monomer component, and having a glass transition temperature of at least 80° C.

A system and method for obscuring road signs by applying an opaque adhesive-backed film to the signs from a roll containing the film. The film and adhesive may be able to conceal sign details sufficiently with only one or two layers of film. The film may be pressure-applied with an adhesive selected so as to adhere sufficiently to the signs or to other layers of film without leaving adhesive or other residue on the signs once removed. The film may be perforated at predetermined intervals to facilitate separation, and the system additionally or alternatively may include a cutter to permit the user to separate the film wherever desired. Various polymers may be used for the film, including polyvinyl chloride (PVC), polyvinylidene chloride (PVDC), polypropylene, low density polyethylene (LDPE), polyester, polyolefin, or other coextruded (CoEX) polymer films. Similarly, various adhesives, including latex-, acrylic-, rubber-, or silicone-based adhesives may be used.

Methods and apparatus to remove gas and vapor from a panel for a decorative layer are disclosed. An example apparatus includes a first press plate of a hot press to engage a first surface of a panel. The hot press is to apply heat to the panel via the first press plate to cure resin of the panel. A first portion of the first press plate is composed of a permeable material to remove at least one of gas or vapor from the panel to deter the at least one of gas or vapor from exerting a pressure on a decorative layer to be coupled to the panel to deter separation of a portion of the decorative layer from the panel.

The present invention relates to a water-resistant mineral-coated cellulose-based substrate, comprising a cellulose-based substrate, and a mineral-coating layer disposed on at least one surface of said substrate, said mineral coating comprising 50-95 wt % of a particulate mineral and 5-50 wt % of a water-dispersible binder based on the total dry weight of the mineral coating, and wherein said mineral-coating layer has been subjected to grafting with a fatty acid halide. The invention further relates to a method for manufacturing the water-resistant mineral-coated cellulose-based substrate.

A pre-fractured glass laminate that includes: a glass substrate comprising a thickness, a pair of opposed primary surfaces, a compressive stress region, a central tension (CT) region and a plurality of cracks; a second phase comprising a polymer or a cured resin within the plurality of cracks; a backing layer; and an interlayer disposed between one of the primary surfaces of the substrate and the backing layer. The compressive stress region extends from each of the primary surfaces to a first selected depth in the substrate. Further, the plurality of cracks is located in the CT region.

A multilayer fluoropolymer film comprising, in order: a first layer comprising a first polymer, the first polymer comprising at least 35 mol percent tetrafluoroethylene comonomer, at least 15 mole percent vinylidene fluoride comonomer, and at least 5 mol percent hexafluoropropylene comonomer, based on the total mol percent of the first polymer; a second layer comprising a second polymer, the second polymer comprising at least 50 mol percent vinylidene fluoride comonomer, based on the total mol percent of the second polymer; and a third layer comprising a third polymer, the third polymer comprising at least 50 mol percent methylmethacrylate comonomer, based on the total mol percent of the third polymer. The multilayer fluoroplymer films are useful for example, in multi-layer film applications (e.g., traffic sign protection, commercial graphic protection, paint protection, windows, windshields, building exteriors, and photo voltaics).