Abstract: Disclosures of the present invention mainly describe an alloy for making trace wires of a touch panel. The alloy consists of a first clapping layer, a copper layer, and a second clapping layer. By applying the alloy as the trace wires of the touch panel, feather-like microstructures are effectively prevented from forming between the trace wires and sensor units of the touch panel. On the other hand, because the alloy is able to completely defense the corrosion attack coming from HNO3-based etchant, the trace wires made of the alloy exhibits an outstanding corrosion resistant during the patterning process of the AgNW-made sensor units. Therefore, during patterning the AgNW-made sensor units, the trace wires can have a large processing window, such that the touch panel is hence able to have a good manufacturing yield rate and possesses an outstanding reliability.

Abstract: Disclosures of the present invention mainly describe an embedded passive device structure, constituted by a first electrically conductive layer, a resistor layer, a dielectric layer, a support layer, a joint layer, and a second electrically conductive layer. Particularly, it is able to form an electronic circuit topology comprising at least one thin film resistor, at least one thin film capacitor and at least one thin film inductor on the embedded passive device structure by applying two times of photolithography processes to the embedded passive device structure. In addition, the resistor layer, formed on the first electrically conductive layer through sputter-coating process, is made of Ni, Cr, W, or compound thereof so as to show the lowest resistance less than or equal to 5 ?/sq because of having good film continuity and surface densification. Moreover, the use of sputter-coating technology is helpful in reduction of industrial waste water.

Abstract: Disclosures of the present invention mainly describe a copper film with buried film resistor. In the present invention, Ni, Cr, W, Ni-based compound, W-based compound, Ni-based alloy, or W-based alloy are adopted for the manufacture of a resistor layer, and a copper layer is processed to the copper film 1 with buried film resistor by being integrated with the resistor layer. Particularly, the resistor layer, formed on the copper layer through sputter-coating process, is able to show the lowest resistance less than or equal to 5 ?/sq. Moreover, the use of sputter-coating technology is helpful in reduction of industrial waste water. In addition, at least one electronic circuit having at least one film resistor can be formed on a printed circuit board comprising the above-mentioned copper film by just needing to complete two times of photolithography processes on the printed circuit board.

Abstract: A wireless charging device includes a flexible carrier member, at least one thin-film transmitter coil assembly and a hanging element. The flexible carrier member includes a main carrier part and at least one sub-carrier part. The at least one sub-carrier part is connected with the main carrier part, so that at least one pocket is defined by the main carrier part and the at least one sub-carrier part collaboratively. Each pocket has an entrance and an accommodation space. The at least one thin-film transmitter coil assembly is disposed within the main carrier part, and emits an electromagnetic wave with at least one specified frequency for wirelessly charging at least one power-receiving device within the accommodation space of the pocket. The hanging element is connected with the main carrier part. The flexible carrier member is hung on an object through the hanging element.

Abstract: A wireless charging device includes a casing, a transmitter coil assembly and a shielding structure. The casing includes a main body with an accommodation space and an entrance. At least one power-receiving device is accommodated within the accommodation space. The transmitter coil assembly is disposed within the main body, and emits an electromagnetic wave with at least one specified frequency for wirelessly charging the at least one power-receiving device. Each transmitter coil assembly includes at least one antenna for receiving an AC signal so as to emit the electromagnetic wave. The shielding structure is attached on an outer surface of the main body or disposed within the main body. The shielding structure at least shields the antenna of the transmitter coil assembly so as to block divergence of the electromagnetic wave.

Abstract: A wireless charging device includes a first separation part, a second separation part, a flexible charging film and a circuit board. The first separation part has a first accommodation space. The second separation part has a second accommodation space. The flexible charging film is retractable back to the first accommodation space of the first separation part. The circuit board is electrically connected with the flexible charging film, and disposed within the second accommodation space of the second separation part. When the second separation part is moved in a direction away from the first separation part, the flexible charging film is stretched so as to wirelessly charge at least one power-receiving device. When the second separation part is moved in a direction toward the first separation part, the flexible charging film is retracted back to the first accommodation space of the first separation part.

Abstract: A wireless charging device includes a main body, at least one transmitter coil assembly, at least one transmitter module, a shielding structure, a movable carrying unit and a controlling unit. Each transmitter coil assembly includes at least one antenna for emitting an electromagnetic wave with at least one specified frequency for wirelessly charging at least one power-receiving device. The movable carrying unit is disposed within an accommodation space of the main body for carrying the at least one power-receiving device. According to a result of judging whether the at least one power-receiving device is introduced into or removed from the accommodation space of the main body through the movable carrying unit, the at least one transmitter module is enabled or disabled by the controlling unit.

Abstract: A thin-film coil assembly includes a flexible substrate, an oscillation starting antenna, a resonant antenna, a first protective layer and a second protective layer. The flexible substrate has a first surface and a second surface opposed to the first surface. The oscillation starting antenna is disposed on the first surface of the flexible substrate. The resonant antenna is disposed on the second surface of the flexible substrate. Moreover, at least one capacitor is connected between a first end and a second end of the resonant antenna. An electromagnetic wave with a specified resonant frequency is emitted or received by the thin-film coil assembly in response to a resonant coupling effect of the resonant antenna and the oscillation starting antenna. The first protective layer covers the oscillation starting antenna. The second protective layer covers the resonant antenna.

Abstract: Disclosure is related to a touch-sensitive panel device and electrode structure therein. The electrode structure is made of metal material. The electrode structure not only eliminates reflective light from the metal layer, but also retain transmittancy and conductivity. The electrode includes a metal conductive layer, a light-trimmed roughened structure and a blackened layer. The trimmed roughened structure is formed in the electrode structure, for example on the metal conductive layer. The trimmed roughened structure is used to eliminate the reflective lights made by the metal conductive layer and the substrate. The trimmed roughened structure may be formed by an etching process applied to the metal conductive layer; or by electrolytic, sputtering, deposition or coating process. The blackened layer is used to absorb the lights reflected from the metal material, and also to reduce color shift of a display. The blackened layer is used to eliminate the metal reflection.

Abstract: Disclosure is related to a thermoelectric power generator. The generator essentially includes a thermoelectric thin-film element which is such as a thin film used to generate voltages according to a temperature difference. The output electric signals are converted to energy stored in an energy storage element. An output circuit is included to output power. In an exemplary embodiment, the thermoelectric power generator has a contact interface for sensing external temperate. The thermoelectric thin-film element is enabled to output voltages when temperature difference is induced. The generator further has a switch, which is used to control if the power is output. The output element is such as a light-emitting element.

Abstract: A gas sensor comprises a layered structure with an ionic conductive film and a high gas-permeability interlayer film, a first catalyst electrode and a second catalyst electrode, a conductivity promotion structure, a high-k layer and a current detecting unit. The ionic conductive film includes a material with ionic conductivity ranging from 0.02 to 1000 S/cm. The first catalyst electrode and second catalyst electrode are located on the layered structure and spaced by a predetermined distance for ionizing a gas and reducing the ionized gas, respectively. The conductivity promotion structure includes a material with electronic conductivity ranging from 10?5 to 105 S/cm, and provides wanted electrons for a reduction reaction. The high-k layer is interposed between the conductivity promotion structure and layered structure. The current detecting unit is coupled to the first catalyst electrode and second catalyst electrode to sense a detecting current with respect to the ionized gas.

Abstract: An electrode structure for a touchscreen is provided. The electrode structure includes a flexible substrate and a plurality of electrode lines, wherein the electrode line includes a first adhesive layer, a second adhesive layer, a conductive layer, a first resist layer and a second resist layer. Through the configuration above, the electrode structure of the present application adheres the flexible substrate strongly by the first adhesive layer, and the second adhesive layer strengthen the adhesion between the first adhesive layer and the conductive layer, so that the conductive layer may be firmly adhered to the flexible substrate, even change the shape of the substrate, the electrode lines are not easy to fall off. The present invention also provides an electrode structure for scattering the reflective metallic luster to make observer imperceptible and reduce the backlight interference.

Abstract: Disclosure is to a thin-film coil component, and a charging apparatus. The thin-film coil is composed of spiral thin-film winding. Within the spiral windings, a gap exists between adjacent spiral structure, A first thin-film winding forms a first connection port for connecting external circuit at an external end, and has a first winding terminal at an internal end. An induced electric field can be formed by supplying electric current via the connection port. Further, a thin-film coil component is made when two thin-film coils with the same spiral direction are fabricated on two opposite surfaces of a substrate. An adhesive layer mixed with Ferromagnetic material is used to combine coils and the substrate. An induced electric field is also created when powering this thin-film coil component. Assembly of one or more thin-film coil components can make the charging apparatus used to electrically charge an electronic device which includes a device-end thin-film coil component.

Abstract: A blackening coating and an electrode structure using the same are provided. The blackening coating has the effect of anti-corrosion and reducing metallic luster for invisibility, thus the blackening layer formed with the present blackening coating can replace the convention resist layer to simplify the process of the electrodes on touch panel, and to achieve the efficacy of cost down and reducing metallic luster.

Abstract: Disclosure is related to a touch-sensitive panel device and electrode structure therein. The electrode structure is made of metal material. The electrode structure not only eliminates reflective light from the metal layer, but also retain transmittancy and conductivity. The electrode includes a metal conductive layer, a light-trimmed roughened structure and a blackened layer. The trimmed roughened structure is formed in the electrode structure, for example on the metal conductive layer. The trimmed roughened structure is used to eliminate the reflective lights made by the metal conductive layer and the substrate. The trimmed roughened structure may be formed by an etching process applied to the metal conductive layer; or by electrolytic, sputtering, deposition or coating process. The blackened layer is used to absorb the lights reflected from the metal material, and also to reduce color shift of a display. The blackened layer is used to eliminate the metal reflection.

Abstract: Present disclosure is related to a touch sensing electrode structure. The structure includes multiple first electrode lines formed along a first direction spaced from each other. Each first electrode line has several first electrode blocks which are electrically connected with a space there-between. The structure also includes multiple second electrode lines along a second direction spaced from each other. The second electrode lines and the first electrode lines are overlapped and insulated. The second electrode line also includes several second electrode blocks which are electrically connected with a space. The every first or second electrode block has a plurality of second wires formed along the second direction and at least one first wire which is electrically connected with the second wires and formed along the first direction.

Abstract: An electrode structure for a touchscreen is provided. The electrode structure includes a flexible substrate and a plurality of electrode lines, wherein the electrode line includes a first adhesive layer, a second adhesive layer, a conductive layer, a first resist layer and a second resist layer. Through the configuration above, the electrode structure of the present application adheres the flexible substrate strongly by the first adhesive layer, and the second adhesive layer strengthen the adhesion between the first adhesive layer and the conductive layer, so that the conductive layer may be firmly adhered to the flexible substrate, even change the shape of the substrate, the electrode lines are not easy to fall off. The present invention also provides an electrode structure for scattering the reflective metallic luster to make observer imperceptible and reduce the backlight interference.

Abstract: Present disclosure is related to a touch sensing electrode structure. The structure includes multiple first electrode lines formed along a first direction spaced from each other. Each first electrode line has several first electrode blocks which are electrically connected with a space there-between. The structure also includes multiple second electrode lines along a second direction spaced from each other. The second electrode lines and the first electrode lines are overlapped and insulated. The second electrode line also includes several second electrode blocks which are electrically connected with a space. The every first or second electrode block has a plurality of second wires formed along the second direction and at least one first wire which is electrically connected with the second wires and formed along the first direction.

Abstract: An electrochemistry apparatus comprises a supporting body and a reaction layer for generating electromotive force. The supporting body is made of a first material. The reaction layer covers the surface of the supporting body and comprises an ion conductive layer, a first film electrode and a second film electrode. The first and the second film electrodes are separately formed on two opposite surfaces of the ion conductive layer. The ion conductive layer is made of a second material having a thermal expansion coefficient approximating to the thermal expansion coefficient of the first material. The second material has an ionic conductivity greater than the ionic conductivity of the first material. The first material has a toughness greater than the second material. The electrochemistry apparatus employs the supporting body with improved toughness and the ion conductive layer with improved ion conductivity, so as to increase sensitivity and thermal shock resistance.

Abstract: A 3D image display device includes a display module, an electrochromic module, a control element and a sensing element. The display module is provided for generating a left-eye image and a right-eye image. The electrochromic module is comprised of a first transparent substrate, a first transparent conductive element, a plurality of first electrochromic elements, an electrolyte layer, a plurality of second electrochromic elements, a second transparent conductive element and a second transparent substrate. The second electrochromic elements are arranged orthogonally with the first electrochromic elements. The control element is provided for switching the voltage of the first and second transparent conductive elements. The sensing element is provided for sensing a rotating direction of the 3D image display device and transmitting a sensing signal to the control element to change the color of the first or second electrochromic element, so as to produce a parallax barrier.