Abstract: Tyre (1) comprising a monitoring device (10) comprising an electronic unit (11) comprising a sensor for detecting at least one of the following physical quantities: temperature, pressure, acceleration, deformation; a processing unit; a transceiver; an electric power supplier (12) having a housing body (50), a first pole (22) and a second pole (24); an electric circuit (18) for connecting the two poles (22, 24) to the electronic unit (11); a flexible support (13) on which the electronic unit is fixed (11), wherein the housing body (50) is fixed onto the flexible support (13) at a first face (23), wherein the monitoring device (10) comprises a tab (26) integral with the flexible support (13) and folded so that a portion (27) of the tab is fixed to a second face (25) of the housing body (50), and wherein the electric circuit (18) comprises a connecting track (28) extending along the tab (26) up to electrically contact the second pole (24).

Abstract: A method of manufacturing a curved electronic device (100) and resulting product. A patterned layer of non-conductive support material (12m) is printed onto a thermoplastic substrate (11) to form a support pattern. An electrical circuit (13,14) is applied onto the support pattern (12), wherein the electrical circuit (13,14) comprises circuit lines (13) comprising a conductive material (13m) applied onto support lines (12b) of the pattern and electrical components (14) applied onto support islands (12a) of the pattern. A thermoforming process (P) is used for deforming (S) the substrate (11) while a relatively high resistance of the support material (12m) to the deforming maintains a structural integrity of the electrical circuit (13,14).

Abstract: Tyre (1) comprising a monitoring device (10) comprising an electronic unit (11) comprising a sensor for detecting at least one of the following physical quantities: temperature, pressure, acceleration, deformation; a processing unit; a transceiver; an electric power supplier (12) having a housing body (50), a first pole (22) and a second pole (24); an electric circuit (18) for connecting the two poles (22, 24) to the electronic unit (11); a flexible support (13) on which the electronic unit is fixed (11), wherein the housing body (50) is fixed onto the flexible support (13) at a first face (23), wherein the monitoring device (10) comprises a tab (26) integral with the flexible support (13) and folded so that a portion (27) of the tab is fixed to a second face (25) of the housing body (50), and wherein the electric circuit (18) comprises a connecting track (28) extending along the tab (26) up to electrically contact the second pole (24).

Abstract: A curved electronic device (10c) can be formed by a stack with a curved substrate (13) comprising a thermoplastic material (Ms), and at least one electronic component (14) connected to an electronic circuit (15) disposed on the substrate (13). A component area (11) of the substrate surface (11.12) around the electronic component (14) comprises a first material (M1) providing relatively low absorption (A1) to light (L) and a surrounding area (12) of the substrate (13) outside the component area (11), comprises a second material (M2) providing relatively high absorption (A2) of the light (L). E.g. as a result of differential heating and thermoforming a first thickness (T1) of the substrate (13) in the component area (11) may be relatively high compared to a second thickness (T2) of the substrate (13) in the surrounding area (12).

Abstract: A method of manufacturing a curved electronic device (100) and resulting product. A patterned layer of non-conductive support material (12m) is printed onto a thermoplastic substrate (11) to form a support pattern. An electrical circuit (13,14) is applied onto the support pattern (12), wherein the electrical circuit (13,14) comprises circuit lines (13) comprising a conductive material (13m) applied onto support lines (12b) of the pattern and electrical components (14) applied onto support islands (12a) of the pattern. A thermoforming process (P) is used for deforming (S) the substrate (11) while a relatively high resistance of the support material (12m) to the deforming maintains a structural integrity of the electrical circuit (13,14).

Abstract: A nozzle for jetting devices is described comprising e.g. one patterned silicon substrate enabling semiconductor mass production. The method of manufacturing the nozzle is characterized by using one mask layer deposited on the silicon substrate. The etching of the silicon substrate is done by means of a first isotropic etching step and a second anisotropic etching step through the mask layer, resulting in a perfectly aligned nozzle.

Abstract: In order to provide a wearable drug delivery device for long term administration of drugs not employing a needle or canula, it is suggested according to the present invention that a wearable drug delivery device comprises a tubular reservoir (1) having an outlet end from which a drug may be expelled and a second end, a high-speed jet pump (2) for transdermal, needle-less micro-jet drug delivery, being connected to the outlet end of the tubular reservoir, a venting valve, being connected to the second end of the reservoir.