A method of layering a layer of circuitry pattern to another layer of circuitry pattern during the manufacturing of a multilayer flexible printed circuit in a reel-to-reel machine. The method includes feeding both layers of circuitry pattern reel-to-reel into the machine, placing a layer of dielectric sheet material on the fly between the two layers of circuitry patterns reel-to-reel, followed by simultaneously passing the two layers of circuitry pattern and the dielectric sheet material under a laser scanner in the reel-to-reel machine to irradiate a laser beam on a layer of circuitry pattern to weld the two layers of circuitry patterns together.

A sensor structure and a method for producing the sensor structure. A base material is applied to a transfer support. The transfer support is arranged on a sensor body, and at least parts of the base material are transferred from the transfer support to the sensor body via local energy input.

It is possible to implement pattern formation and pattern manufacturing that eliminate the necessity of high-cost accurate positioning. A pattern manufacturing apparatus (100) includes a controller (101) and a laser projector (102). The controller (101) controls the laser projector (102) to form a pattern on a pattern forming sheet (130) placed on a stage (140). The laser projector (102) further includes an optical engine (121). The optical engine (121) irradiates the pattern forming sheet (130) with a light beam (122). The stage (140) has a hollow structure not to obstruct the optical path of the light beam (122). The pattern forming sheet (130) includes a light-transmitting sheet material layer and a photo-curing layer applied to the sheet material layer.

The present invention relates to a method for producing radio frequency identification devices (RFID) without personalized chip, in particular the production of RFID tags without personalized chip, also referred to as chipless RFID tags. The present invention also relates to devices and labels produced by the claimed method as well as to systems for producing said devices/labels.

A method and structure for forming conductive structure such as an electric circuit, or a portion of an electric circuit, can include the use of a thermal print head and a ribbon including a carrier and a metal layer. The thermal print head is used to print a first portion of the metal layer onto a sacrificial print medium. The first portion printed has a first pattern, where a second portion having a second pattern remains on the carrier. The first pattern is a reverse image at least a portion of the electric circuit, while the second pattern includes at least a portion of the electric circuit. The second portion having the second pattern can be transferred to a circuit substrate, then used as an electric circuit.

A conductive trace interconnect tape for use with a printed circuit board or a flexible circuit substrate comprises a top insulating layer, an electrically conductive layer, and a bottom insulating layer. The top insulating layer is formed from electrically insulating material and is configured to provide electrical isolation from electrically conductive objects that are positioned on top of the conductive trace interconnect tape. The electrically conductive layer is positioned underneath the top insulating layer. The electrically conductive layer is formed from electrically conductive material and includes electrical interconnect traces, electrical component pads, or electrically conductive planar portions. The bottom insulating layer is positioned underneath the electrically conductive layer. The bottom insulating layer is formed from electrically insulating material and is configured to provide electrical isolation from electrically conductive objects that are positioned on the printed circuit board or flexible circuit substrate.

A method to remove slugs from a circuitry pattern on the fly during the fabrication of a flexible printed circuit, the method includes applying a coverlay reel-to-reel onto one side of the metal foil on the fly and applying a sacrificial liner reel-to-reel onto another side of the metal foil on the fly. Then, after the slugs and circuitry patterns are created from laser ablation, the slug can be removed by applying compressed air to the slugs and/or peeling off the sacrificial liner from the circuitry pattern reel-to-reel.

A method and apparatus for producing an electronic device are disclosed. An adhesive material is jetted in a first pattern on a surface of a receiver substrate. A carrier having a metal foil disposed thereon is brought into contact with the first substrate such that a portion of the metal foil contacts the adhesive material. The adhesive material is activated using at least one of mechanical pressure and heat while the portion of the metal foil is in contact with the adhesive material. The first substrate and the second substrate are separated, whereby the portion of the metal foil is transferred to the first substrate.

A method and structure for forming conductive structure such as an electric circuit, or a portion of an electric circuit, can include the use of a thermal print head and a ribbon including a carrier and a metal layer. The thermal print head is used to print a first portion of the metal layer onto a sacrificial print medium. The first portion printed has a first pattern, where a second portion having a second pattern remains on the carrier. The first pattern is a reverse image at least a portion of the electric circuit, while the second pattern includes at least a portion of the electric circuit. The second portion having the second pattern can be transferred to a circuit substrate, then used as an electric circuit.

The present invention relates to a printing method comprising a step of printing a pattern on a substrate, preferably by ink jet printing, followed by a gold plating step by means of contact between the pre-printed pattern to be gold plated and a gold plating deposition device, such as a preferably conductive metal sheet, e.g. a multilayer film comprising a preferably conductive metal sheet.