Disclosed is a method for connecting a connecting face of an edge material to a connecting face of a workpiece by a synthesis element, including the steps: of making available the workpiece, feeding the synthesis element, which is made available by at least one function film composed of an adhesive, activating the adhesive function film, applying the synthesis element to one of the connecting faces, connecting the synthesis element to the other of the connecting faces, wherein the workpiece and the edge material are connected by the synthesis element located between them. Furthermore, there is disclosed a synthesis element and a device for connecting a connecting face of an edge material to a connecting face of a workpiece.

The invention relates to an apparatus for fitting an edge profile on a narrow surface of a panel-form material in an edge-banding apparatus, having a panel carrier for accommodating a panel-form material. The panel carrier has an upper side running in a plane, having an edge-profile-feeding device, and having an edge-profile guide, said guide having at least one guide means along which or through which can be guided the edge profile. This can be fed by the edge-profile-feeding device. In order to prevent or reduce offsetting in the corner region of the panel-form material, the invention proposes that the at least one guide means should be movable relative to the panel carrier in a direction running at an angle to the plane in which the upper side of the panel carrier runs. The invention also relates to a method for fitting an edge profile, and to a furniture part produced thereby.

This disclosure is related to a method for applying insulative coating to a carbon-fiber exposed end of a composite material part using a dispenser device. The dispenser device includes a nozzle discharging a first material or a mixed material obtained by mixing the first material and a second material. The method includes discharging the first material or the mixed material from the nozzle toward the carbon-fiber exposed end, and applying the first material or the mixed material to the carbon-fiber exposed end such that the carbon-fiber exposed end is covered with the insulative coating.

A system for feeding a coating material from at least one movable modular unit to a coating device is provided, the at least one movable modular unit being provided for the storage and provision of roll-type or coil-type coating material units including edge strips for applying to a narrow side of panel-type workpieces. A feed section holds and transports the coating material. A cassette unit guides the coating material provided by the feed section. A coupling section couples the at least one movable modular unit to the feed section, the at least one movable modular unit holding coating material units.

A plywood panel includes multiple softwood layers and multiple hardwood layers that alternatively-tacked and bonded each other using adhesive. The face and the back of the plywood panel are both softwood layers. The number of the multiple softwood layers is one more than the number of the multiple hardwood layers. A single a paper veneer glued to the top-most softwood layer. A single layer of paper veneer is attached to the top-most softwood layer.

A plywood panel includes multiple softwood layers and multiple hardwood layers that alternatively-tacked and bonded each other using adhesive. The face and the back of the plywood panel are both softwood layers. The number of the multiple softwood layers is one more than the number of the multiple hardwood layers. A single a paper veneer glued to the top-most softwood layer. A single layer of paper veneer is attached to the top-most softwood layer.

To improve the reliability of fire resistance with regard to wood materials containing a fireproofing treatment agent such as a semi-incombustible wood material while also improving both the ease of procuring raw materials and mass productivity, a panel board includes front/back veneers constituting the front and back thereof and a core veneer layer between the front/back veneers. The veneer fiber direction of the front/back veneers is substantially parallel to the lengthwise direction of the panel board. The core veneer layer is a layer obtained by stacking a plurality of sheets of core veneer in the thickness direction. The veneer fiber directions of all of the sheets of the core veneer are substantially orthogonal to the lengthwise direction of panel board. The front/back veneers has a thickness of 1.5-4.0 mm, and the thickness of the core veneer layer 31 is equal to or greater than the total thickness of the front/back veneer 21. Lathe checks and cracks are exposed on the board grain surfaces of all the front/back veneer 21, and an aqueous solution of a fireproofing agent is infiltrated therefrom.

To improve the reliability of fire resistance with regard to wood materials containing a fireproofing treatment agent such as a semi-incombustible wood material while also improving both the ease of procuring raw materials and mass productivity, a panel board includes front/back veneers constituting the front and back thereof and a core veneer layer between the front/back veneers. The veneer fiber direction of the front/back veneers is substantially parallel to the lengthwise direction of the panel board. The core veneer layer is a layer obtained by stacking a plurality of sheets of core veneer in the thickness direction. The veneer fiber directions of all of the sheets of the core veneer are substantially orthogonal to the lengthwise direction of panel board. The front/back veneers has a thickness of 1.5-4.0 mm, and the thickness of the core veneer layer 31 is equal to or greater than the total thickness of the front/back veneer 21. Lathe checks and cracks are exposed on the board grain surfaces of all the front/back veneer 21, and an aqueous solution of a fireproofing agent is infiltrated therefrom.

This method for manufacturing a high-density strand board enables high-density strand boards to be formed by using about the same press pressure as press pressures required to form strand boards with common densities, so that the high-density strand boards can be produced without using special facilities and equipment. A pretreatment process P2 is performed on strands 5 before pressing. The pretreatment process P2 is comprised of a first treatment process P2a and a subsequent second treatment process P2b. At least one of beating, high-frequency treatment, high-temperature high-pressure treatment, high-water pressure treatment, repeated deaeration and dehydration treatment, and chemical treatment is performed in the first treatment process P2a, and roll pressing or flat press pressing is performed in the second treatment process P2b. A strand board B with a density of 750 to 950 kg/m.sup.3 is formed by using a press pressure of 4 N/mm.sup.2 or less.

This disclosure is related to a method for applying insulative coating to a carbon-fiber exposed end of a composite material part using a dispenser device. The dispenser device includes a nozzle discharging a first material or a mixed material obtained by mixing the first material and a second material. The method includes discharging the first material or the mixed material from the nozzle toward the carbon-fiber exposed end, and applying the first material or the mixed material to the carbon-fiber exposed end such that the carbon-fiber exposed end is covered with the insulative coating.