A solid electrolyte composition includes: an inorganic solid electrolyte (A) having ion conductivity of a metal belonging to Group 1 or Group 2 in the periodic table; a binder (B); and a dispersion medium (C), in which the binder (B) includes a first binder (B1) that precipitates by a centrifugal separation process and a second binder (B2) that does not precipitate by the centrifugal separation process, the centrifugal separation process being performed in the dispersion medium (C) under a specific condition, and a content X of the first binder (B1) and a content Y of the second binder (B2) satisfy the following expression,
0.10≤Y/(X+Y)≤0.80.

A solid electrolyte composition includes: an inorganic solid electrolyte (A) having ion conductivity of a metal belonging to Group 1 or Group 2 in the periodic table; a binder (B); and a dispersion medium (C), in which the binder (B) includes a first binder (B1) that precipitates by a centrifugal separation process and a second binder (B2) that does not precipitate by the centrifugal separation process, the centrifugal separation process being performed in the dispersion medium (C) at a temperature of 25° C. at a centrifugal force of 610000 G for 1 hour, and a content X of the first binder (B1) and a content Y of the second binder (B2) satisfy the following expression,
0.01≤Y/(X+Y)<0.10.

A manufacturing method of an embedded metal mesh flexible transparent electrode and application thereof; the method includes: directly printing a metal mesh transparent electrode on a rigid substrate by using an electric-field-driven jet deposition micro-nano 3D printing technology; performing conductive treatment on a printed metal mesh structure through a sintering process to realize conductivity of the metal mesh; respectively heating a flexible transparent substrate and the rigid substrate to set temperatures; completely embedding the metal mesh structure on the rigid substrate into the flexible transparent substrate through a thermal imprinting process; and separating the metal mesh completely embedded into the flexible transparent substrate from the rigid substrate to obtain the embedded metal mesh flexible transparent electrode. The mass production of the large-size embedded metal mesh flexible transparent electrode with low cost and high throughput by combining the electric-field-driven jet deposition micro-nano 3D printing technology with the roll-to-plane thermal imprinting technology.

Proposed is a method of forming an electrode on a surface of an object by using inkjet printing, the method including forming a buffer on an outer edge of an electrode formation position, and forming the electrode by filling electrode ink inside the buffer, wherein the buffer formation is performed by stacking buffer layers formed by inkjet printing of buffer ink, and hydrophilicity of a surface of each of the buffer layers is lower than hydrophilicity of the object surface. According to an electrode forming apparatus, the buffer constituting the outer edge of the electrode is formed high and the electrode ink is filled inside the buffer to form the electrode, thereby enabling the formation of the electrode having an increased sectional area.

A bi-wire audio cable system designed to reduce propagation velocity (V.sub.p) differentials between low and high frequencies within the audio band, by adjusting the resistive and capacitive components of the cables. By utilizing two cables, one for low frequencies and one for high frequencies, with different characteristics, the impedance of the cables can be configured to be relatively consistent across the audio spectrum, minimizing the change in V.sub.p, thereby increasing audio fidelity. The bi-wire audio system can include a first (e.g. high frequency) cable with a first plurality of insulated conductors having a first conductor gauge; and a second (e.g. low frequency) cable with a second plurality of insulated conductors having a second, larger conductor gauge. The cables can be connected together at an output of an amplifier, and can be connected to corresponding low and high frequency inputs of a speaker (e.g. a woofer and tweeter).

Provided is ITO particles satisfying a relationship expressed in Expression (1) given below. 16×S/P.sup.2≤0.330 . . . (1) (In the expression, S indicates a particle area in a TEM photographed image, and P indicates a perimeter of the particle).

Provided is ITO particles satisfying a relationship expressed in Expression (1) given below. 16×S/P.sup.2≤0.330 . . . (1) (In the expression, S indicates a particle area in a TEM photographed image, and P indicates a perimeter of the particle).

A flexible flat cable manufacturing system comprises a tape conveying device conveying an adhesive tape along a first direction, and a wire conveying device conveying a row of wires along a second direction perpendicular to the first direction and parallel to a width direction of the conveyed adhesive tape. A wire pressing device presses and pastes the part of the row of wires facing the adhesive tape onto the adhesive tape. A wire cutting device cuts the row of wires to obtain a row of wire segments pasted on the adhesive tape and separated from the row of wires and produces a flexible flat cable including the adhesive tape and the wire segments pasted on the adhesive tape.

Bendability of a copper alloy wire is improved without decrease in an electrical conductivity of the copper alloy wire made of copper alloy containing zirconium. A cable includes: a two-core stranded wire formed by intertwining two electrical wires made of a conductor and an insulating layer covering the conductor; a filler formed around the two-core stranded wire; and a sheath formed around the filler and the electrical wire. The conductor is a copper alloy wire in which a precipitate containing the zirconium disperses, and has a crystal gain diameter that is equal to or smaller than 1 μm, an electrical conductivity that is equal to or higher than 87% IACS, and a tensile stress that is equal to or larger than 545 MPa.

A heating assembly configured to receive a power cable for restoring an insulation system of the power cable, the heating assembly including: a central pressurisation and heating structure, and a first and second lateral structure provided at a respective axial end of the central pressurisation and heating structure, the first and second lateral structure each having at least a 20 cm long axially extending section primarily made of a material at most having a conductivity of the order of 1000 S/m at 20° C.