Provided is a flooring tile manufacturing apparatus includes: a lower sheet supply unit configured to form and supply a lower sheet; a middle sheet supply unit configured to supply a middle sheet joined to an upper side of the lower sheet; a raw material supply unit configured to supply materials having different contents of a filler to the lower sheet supply unit and the middle sheet supply unit; a main roller configured to join the lower sheet and the middle sheet that have been received; a first sheet supply unit configured to supply a print sheet having a color or a pattern to the main roller; a second sheet supply unit configured to supply a transparent sheet to the main roller; and an ultraviolet (UV) coating unit configured to form a UV coating layer on a surface of the transparent sheet.

Among other things a method including releasing a discrete component from an interim handle and depositing a discrete component on a handle substrate, attaching the handle substrate to the discrete component, and removing the handle substrate from the discrete component.

The invention relates to a bamboo floor, in particular to a composite bamboo floor. The composite bamboo floor comprises a floor surface board provided with a body, a pressed surface, a connecting surface connected with the core board, at least one cut surface board side face and surface board end faces, and the core board arranged under the floor surface board and provided with a core board surface connected with the floor surface board, a core board bottom surface, core board side faces and core board end faces, and the positions of the core board side faces or the core board side faces and the surface board side faces are provided with notch structures processed in two sides in the length direction of the composite bamboo floor. The composite bamboo floor is high in strength, high in processing efficiency and low in production cost.

An optical element fabrication method including following steps are provided. First, a micro-lens layer including a micro-lens and a first substrate is provided. Besides, a micro optical channel layer including a micro optical channel and a second substrate is provided. A first bonding process is performed to bond the micro-lens layer to the micro optical channel layer, wherein the micro-lens is corresponded to the micro optical channel in a direction that is perpendicular to the surface of the second substrate, and the first substrate of the micro-lens layer is removed later.

A continuous manufacturing equipment of an elastic three-dimensional fabric and a continuous manufacturing method thereof are disclosed. The continuous manufacturing equipment includes: a film conveying device having a thermal melting film and a conveying mechanism; a cutting device used for cutting a plurality of cutting gaps on the thermal melting film; a first fabric laminating device adhering an outer fabric on one surface of the thermal melting film; and a second fabric laminating device adhering an elastic fabric on another surface of the thermal melting film in a manner of elastically stretching and then elastically recovering. As such, effects of automatic, continuous, and simple steps in manufacturing and having a high yield rate are provided.

The present invention generally relates to the modification of a deep-drawing sheet blank (P) for electric resistance heating. Generally, the modified sheet blank comprises slits (Z) being made in the edges of the blank (P) transversely to the electric current flow and oriented towards the perimeter of the forming zone (T). The distances between the ends of the slits (Z) and the forming zone (T) perimeter may be equal. The ends of the slits (Z) oriented towards the forming zone perimeter (T) may also be rounded.

Provided is a method for producing a packing sheet with improved insulation and storage properties, which can greatly reduce logistics costs by minimizing a volume during storage and transportation and also greatly increase insulation.

An electronic component includes a wiring substrate, surface mount devices mounted on a front surface of the wiring substrate, and a shield plate fixed on a side adjacent to top surfaces of the surface mount devices. The shield plate includes a magnetic ceramic sintered sheet and a first metal film. The magnetic ceramic sintered sheet includes a first main surface and a second main surface. The first metal film is disposed on the first main surface of the magnetic ceramic sintered sheet.

A reclosably sealed cup including a cup having a sealing perimeter, a lid having a reclosable sealing arrangement, associated with the sealing perimeter. The lid is adapted to reclosably cover the cup, and the reclosable sealing arrangement adapted to reclosably seal the cup along the sealing perimeter. The reclosably sealed cup further includes an interfacial arrangement, interdisposed between the sealing perimeter and the reclosable sealing arrangement. The interfacial arrangement has a first surface disposed towards, and forming a base adhesive attachment with, the sealing perimeter, and a second surface, distal to the first surface, disposed towards the reclosable arrangement, and forming a reclosable adhesive attachment therewith.

A traction mat wherein the foam is reinforced with a layer of fabric, fiber, or reinforced adhesive between the CLCC foam layer and the substrate or underlying surface. The layering is preferably a first foam layer and a fabric layer impregnated with a pressure sensitive adhesive. This prevents the CLCC foam from being bonded directly to the substrate and allows the fabric/fiber to support the CLCC foam such that the entire assembly can be removed in one piece without the CLCC foam disintegrating. The fabric layer may be replaced with a double-sided adhesive reinforced by a variety of woven and non-woven fibers. The introduction of the reinforcing fabric and/or fiber layer eliminates any residual CLCC foam from being bonded to the substrate. Consequently, the traction mat can be easily lifted away and removed.