The present invention relates to a method for manufacturing an angle and curvature detection sensor, and the sensor and, more specifically, to: a method for manufacturing a thin-film transistor array-based backplane by a roll-to-roll gravure printing process and manufacturing a sensor for measuring an angle change and a degree of curvature of the X axis and the Y axis by using the backplane; and the sensor. The method for manufacturing an angle and curvature detection sensor, according to an embodiment of the present invention, comprises the steps of: manufacturing a thin-film transistor backplane by a roll-to-roll gravure printing process; forming a protective layer on the thin-film transistor backplane by printing; forming a sealed space by adhering a flexible plastic case onto the upper part of the protective layer by means of an adhesive; and filling the sealed space with a first liquid and injecting a second liquid.

The present invention relates to a method for manufacturing an angle and curvature detection sensor, and the sensor and, more specifically, to: a method for manufacturing a thin-film transistor array-based backplane by a roll-to-roll gravure printing process and manufacturing a sensor for measuring an angle change and a degree of curvature of the X axis and the Y axis by using the backplane; and the sensor. The method for manufacturing an angle and curvature detection sensor, according to an embodiment of the present invention, comprises the steps of: manufacturing a thin-film transistor backplane by a roll-to-roll gravure printing process; forming a protective layer on the thin-film transistor backplane by printing; forming a sealed space by adhering a flexible plastic case onto the upper part of the protective layer by means of an adhesive; and filling the sealed space with a first liquid and injecting a second liquid.

A system for dosing one or more fluids on a substrate, the system comprising a rotating roll. The rotating roll has a central longitudinal axis, wherein the rotating roll rotates about the central longitudinal axis; an exterior surface defining an interior region and substantially surrounding the central longitudinal axis; and a vascular network configured for transporting the one or more fluids in a predetermined path from the interior region to the exterior surface of the rotating roll.

A method of creating a vascular network for printing a fluid onto a substrate is disclosed. The method includes the steps of: determining a deposit objective; selecting a fluid having at least one fluid property; designing a vascular network to achieve the deposit objective; selecting a fluid delivery system, and depositing the fluid in liquid form that solidifies into the vascular network according to the deposit objective.

Provided are a gravure cylinder, which has satisfactory wear resistance as the gravure cylinder and includes a surface reinforcing coating layer having wear resistance equal to or more than that of chromium plating using hexavalent chromium, a method of manufacturing the gravure cylinder, and a method of manufacturing a printed matter using the gravure cylinder. The gravure cylinder includes: a plate base material; a recess layer, which is formed on a surface of the plate base material and includes a large number of recesses formed on the surface; and a surface reinforcing coating layer configured to cover the recess layer with chromium nitride or carbon nitride, in which the surface reinforcing coating layer is formed by reactive sputtering.

Provided are a gravure cylinder, which has satisfactory wear resistance as the gravure cylinder and includes a surface reinforcing coating layer having wear resistance equal to or more than that of chromium plating using hexavalent chromium, a method of manufacturing the gravure cylinder, and a method of manufacturing a printed matter using the gravure cylinder. The gravure cylinder includes: a plate base material; a recess layer, which is formed on a surface of the plate base material and includes a large number of recesses formed on the surface; and a surface reinforcing coating layer configured to cover the recess layer with chromium nitride or carbon nitride, in which the surface reinforcing coating layer is formed by reactive sputtering.

Provided are a functional cylinder body, including a plurality of layers having magnetic patterns and non-magnetic patterns formed adjacently, and a manufacturing method therefor. The functional cylinder body comprises at least: a cylinder main body; a first functional pattern part, which includes first patterns and first functional patterns, the first patterns having first recess patterns and first non-recess patterns formed by forming recesses on a first material layer made of any one of a magnetic material and a non-magnetic material, the first functional patterns being made of any one of the magnetic material and the non-magnetic material embedded in the first recess patterns; and a second functional pattern part, which is formed in a position of the cylinder main body shallower than a position of the first recess patterns and has magnetic patterns of the magnetic material and non-magnetic patterns of the non-magnetic material formed adjacently.

Provided are a functional cylinder body, including a plurality of layers having magnetic patterns and non-magnetic patterns formed adjacently, and a manufacturing method therefor. The functional cylinder body comprises at least: a cylinder main body; a first functional pattern part, which includes first patterns and first functional patterns, the first patterns having first recess patterns and first non-recess patterns formed by forming recesses on a first material layer made of any one of a magnetic material and a non-magnetic material, the first functional patterns being made of any one of the magnetic material and the non-magnetic material embedded in the first recess patterns; and a second functional pattern part, which is formed in a position of the cylinder main body shallower than a position of the first recess patterns and has magnetic patterns of the magnetic material and non-magnetic patterns of the non-magnetic material formed adjacently.

An imaging printing form having a base body with an elastomeric coating, in which the elastomeric coating carries an engraving pattern. The elastomeric coating has a hard rubber with a hardness of greater than 40 Shore D, and more particularly greater than 70 Shore D. The hard rubber is based on butadiene-acrylonitrile rubber (NBR), carboxyl group-containing nitrile rubber (XNBR), hydrogenated acrylonitrile butadiene Rubber (HNBR) or combinations thereof.

An imaging printing form having a base body with an elastomeric coating, in which the elastomeric coating carries an engraving pattern. The elastomeric coating has a hard rubber with a hardness of greater than 40 Shore D, and more particularly greater than 70 Shore D. The hard rubber is based on butadiene-acrylonitrile rubber (NBR), carboxyl group-containing nitrile rubber (XNBR), hydrogenated acrylonitrile butadiene Rubber (HNBR) or combinations thereof.