The invention relates to a floor. The polymer solid wood composite flooring includes a SPC stone plastic layer, and a solid wood veneer layer or plywood layer forming the main body of the floor is arranged under the SPC stone plastic layer; the physical and chemical performance index of the polymer solid wood composite flooring is: color fastness≥Grade 6; average peel strength≥75 (N/50 mm), pollution resistance≥grade 5, heating dimensional change rate≤0.25%, heating warpage≤2.0 mm, moisture content 6-10%. The preparation process of polymer solid wood composite flooring includes: preparation of SPC stone plastic layer; preparation of solid wood veneer layer or plywood layer; composite pressing; first balance treatment; Slitting; second balance treatment; slotting; UV layer preparation. Thereby, the polymer solid wood composite flooring with good foot feeling, not easy to deform and crack, and small dimensional change rate is produced.

The transparent conductive layer (3) includes a first main surface (5), and a second main surface (6) opposed to the first main surface (5) in a thickness direction. The transparent conductive layer (3) has a first grain boundary (7) in which two end edges (23) in a cross-sectional view are both opened to the first main surface (5) and an intermediate region (25) between the end edges (23) is not in contact with the second main surface (6); and a first crystal grain (31) partitioned by the first grain boundary (7) and facing only the first main surface (5). The transparent conductive layer (3) contains rare gas atoms having a higher atomic number than argon atoms.

The present invention is directed to a monoaxially oriented multilayer film suitable for shrink lidding applications.

Provided are a hose excelling in a lightweight property and in fatigue fracture resistance, a method for manufacturing the hose, and a hydraulic pump. The hose includes a tube, an interior of the tube being hollow, continuous carbon fibers and/or continuous glass fibers wound around an outer circumference of the tube, and a thermosetting resin present external to the tube. The thermosetting resin has an elastic modulus from 0.5 to 10 MPa, and the continuous carbon fibers and/or continuous glass fibers are impregnated with at least a part of the thermosetting resin. The elastic modulus of the thermosetting resin is a numeric value determined by: heating the thermosetting resin for 2 hours at a curing temperature of the thermosetting resin; then subjecting the thermosetting resin to thermoregulation for two weeks under a condition of a temperature of 23° C. and a relative humidity of 55%; and then performing a measurement in accordance with JIS K7161:2019.

The present invention provides a heat shrinkable multilayer film that can prevent layer misalignment at a center seal portion and thereby provide a labelled container having excellent appearance when the film is attached to a container as a heat shrinkable label for dry heat shrinking, and a heat shrinkable label including the heat shrinkable multilayer film as a base film. Provided is a heat shrinkable multilayer film including: front and back layers each containing a polyester resin; an interlayer containing a polystyrene resin; and adhesive layers, wherein the front and back layers and the interlayer are stacked with the adhesive layers interposed therebetween, and the heat shrinkable multilayer film has a maximum shrinkage stress of 3.5 to 11 MPa when immersed in hot water at 80° C. for 30 seconds.

An in-mold foamed molded product unit may include an in-mold foamed molded product made of a thermoplastic resin, and an insert material. At least a portion of the insert material may be embedded in the in-mold foamed molded product. The insert material may have a frame-like shape that is substantially rectangular shape and includes a first set of opposite sides and a second set of opposite sides. A portion of the insert material that corresponds to the first set of opposite sides may be a first extending portion, and a portion of the insert material that corresponds to the second set of opposite sides may be a second extending portion. The first extending portion may be substantially entirely embedded in the in-mold foamed molded product, and the second extending portion may include an exposed portion that is exposed to the outside of the in-mold foamed molded product.

An in-mold foamed molded product unit may include an in-mold foamed molded product made of a thermoplastic resin, and an insert material. At least a portion of the insert material may be embedded in the in-mold foamed molded product. The insert material may have a frame-like shape that is substantially rectangular shape and includes a first set of opposite sides and a second set of opposite sides. A portion of the insert material that corresponds to the first set of opposite sides may be a first extending portion, and a portion of the insert material that corresponds to the second set of opposite sides may be a second extending portion. The first extending portion may be substantially entirely embedded in the in-mold foamed molded product, and the second extending portion may include an exposed portion that is exposed to the outside of the in-mold foamed molded product.

A glass substrate comprises a glass clad layer fused to a glass core layer. The glass core layer comprises a core glass composition having an average core coefficient of thermal expansion (CTE.sub.core) and the glass clad layer comprises a clad glass composition having an average clad coefficient of thermal expansion (CTE.sub.clad) that is less than the CTE.sub.core. A maximum tensile stress in the glass core layer is less than 15 MPa.

A glass substrate comprises a glass clad layer fused to a glass core layer. The glass core layer comprises a core glass composition having an average core coefficient of thermal expansion (CTE.sub.core) and the glass clad layer comprises a clad glass composition having an average clad coefficient of thermal expansion (CTE.sub.clad) that is less than the CTE.sub.core. A maximum tensile stress in the glass core layer is less than 15 MPa.

A composite textile fabric that includes a first (face) fabric layer, and a second (back) fabric layer that is formed concurrently with the first fabric layer in a plaited construction. The second fabric includes a plurality of anchored regions at which the second fabric layer is anchored to, and in intimate contact with, the first fabric layer. The second fabric layer also includes a plurality of floating regions, overlying and unattached to the first fabric layer, interspersed between the anchored regions.