Embodiments of the present disclosure provide a flexible UHF RFID anti-metal tag including a tag chip, an antenna layer, a substrate layer and a metal base layer sequentially attached from top to bottom. The substrate layer includes a first and a second dielectric layer being sequentially attached from top to bottom. The first dielectric layer is attached to the antenna layer, and the second dielectric layer is attached to the metal base layer. A metal member to be labeled and the metal base layer jointly eliminate the interference of the metal on an equivalent circuit of the antenna. The substrate layer uses a polymer material as the first dielectric layer, and a support flexible material with the lower cost, such as the foam dielectric layer, is used as the second dielectric layer, which saves cost while ensuring sufficient flexibility of the substrate layer.

Disclosed embodiments generally relate to a transaction card with a fabric inlay. The transaction card may include a housing component having a first housing surface opposite a second housing surface and an inlay component having a first inlay surface opposite a second inlay surface. The inlay and housing may be joined along the second inlay surface and the first housing surface. In addition, the first inlay surface may include a fabric material and a backer layer configured to support the fabric material of the first inlay surface.

A component support fixture having a plurality of oversized compartments of the same size mounted on a top surface of an anisotropic adhesive film such that each of a plurality of burned-in components of different heights and widths are accommodated within a compartment. Patterned traces are formed on the bottom surface of the anisotropic film. The leads of the burned-in components are in electrically communication with those traces through the anisotropic film.

The invention relates to a method for producing a rubber component (1), in the case of which at least one electronic assembly (2) is embedded between a lower and an upper ply (10, 11) of a rubber material, comprising the steps: a) providing a length portion of the lower ply (10) of the rubber material, which is equipped, on the top side (100), with at least one electronic assembly (2); b) stationarily positioning the length portion of the lower ply (10); c) unrolling a length portion of the upper ply (11) of the rubber material on the top side (100) of the stationary length portion of the lower ply (10) in an unrolling direction (A), and fixedly adhesively connecting the length portions of the plies (10, 11) of the rubber material so as to embed the at least one electronic assembly (2); d) conveying out the length portion of the rubber component (1). A corresponding device for producing the rubber components (1) is also specified.

Disclosed embodiments generally relate to a transaction card with a fabric inlay. The transaction card may include a housing component having a first housing surface opposite a second housing surface and an inlay component having a first inlay surface opposite a second inlay surface. The inlay and housing may be joined along the second inlay surface and the first housing surface. In addition, the first inlay surface may include a fabric material and a backer layer configured to support the fabric material of the first inlay surface.

A label stack assembly and method and system for preparing the label stack assembly is disclosed herein. The label stack assembly may be applied to a product in order to provide care instructions in multiple different languages. Individual pages of the label stack assembly may have separate content, such as translations of care instructions into multiple languages, and may be marked by tabs of various shapes, sizes, or styles that may protrude from an edge of the label stack assembly. Tabs may be marked with country codes indicating the translations or other information. The pages of the label stack assembly may be printed on both a front and a back side, such as may be desired, in order to minimize the number of pages used while maximizing the number of care instruction translations or other content pages.

The present invention relates to a lining tube for renovating fluid-conducting pipe systems, wherein the lining tube comprises at least one thermally and/or radiation curable layer and at least one machine-readable data tag, wherein the at least one data tag comprises at least one individual technical specification for the lining tube, which can be processed by a data processing device in order to provide parameters for a curing apparatus, in particular for controlling or regulating a curing process of the lining tube and/or a pulling device, in particular for controlling or regulating pulling in the lining tube.

Among other things, a sheet has a thickness and extends in two dimensions normal to the thickness of the sheet. Within the sheet there is an electronic device having an integrated circuit and conductive elements connected to the integrated circuit. The electronic device extends in the two dimensions, the extent of the device in each of the two dimensions being greater than 3 mm.

Disclosed embodiments generally relate to a transaction card with a fabric inlay. The transaction card may include a housing component having a first housing surface opposite a second housing surface and an inlay component having a first inlay surface opposite a second inlay surface. The inlay and housing may be joined along the second inlay surface and the first housing surface. In addition, the first inlay surface may include a fabric material and a backer layer configured to support the fabric material of the first inlay surface.

A multilayer magnetic sheet is described which comprises a plurality of stacked magnetic component layers separated by first electrically insulating layers. Each of the plurality of magnetic component layers comprises a plurality of isolated magnetic sublayers having a magnetic layer thickness of less than one micron. The multilayer magnetic sheet has a magnetic fraction between about 5% and about 80%; a total magnetic thickness of greater than or equal to 5 microns; and a relative composite permeability of greater than about 20.