An inking system for use in transferring ink to a gravure printing surface in a gravure printing system includes a gravure cylinder r having a printing zone located between first and second recessed bearing contact zones. A radius of the recessed bearing contact zones is less than a radius of the printing zone by at least 0.100 inches. An ink tray includes a floor and first and second end walls. Bearings are mounted outside of the end walls which engage with the first and second bearing contact zones, respectively, thereby positioning the ink tray assembly in a specified position relative to the gravure cylinder. Upper edges of the end walls extend into the recessed bearing contact zones.

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.

Provided is a sensor comprising a non-conductive substrate; and a conductive layer electronically printed on one side of the substrate, wherein the conductive layer comprises: an antenna pattern for transmitting and receiving a radio signal with an external device; a sensing electrode connected to the antenna pattern via a circular wiring for sensing an impedance change due to contact with a sensing target material; and a coating electrode stacked on the sensing electrode for removing an occurrence of noise of the impedance change. Accordingly, the present invention solves the problem of a sensor, in the form of a terminal, not being compact and the problem of high manufacturing costs and low manufacturing quality of a sensor manufactured using a deposition method in order to replace such sensor with a sensor manufactured by a printing method, and solves a corrosion problem of a sensing electrode, a durability problem, etc. that may occur in the sensor of the printing method.

Provided is a sensor comprising a non-conductive substrate; and a conductive layer electronically printed on one side of the substrate, wherein the conductive layer comprises: an antenna pattern for transmitting and receiving a radio signal with an external device; a sensing electrode connected to the antenna pattern via a circular wiring for sensing an impedance change due to contact with a sensing target material; and a coating electrode stacked on the sensing electrode for removing an occurrence of noise of the impedance change. Accordingly, the present invention solves the problem of a sensor, in the form of a terminal, not being compact and the problem of high manufacturing costs and low manufacturing quality of a sensor manufactured using a deposition method in order to replace such sensor with a sensor manufactured by a printing method, and solves a corrosion problem of a sensing electrode, a durability problem, etc. that may occur in the sensor of the printing method.

A rotogravure printing machine has a shaft that rotates and a rotogravure cylinder sleeve for rotation with the shaft. An annular end plate connects to the shaft, and the end plate has a contact surface for contact with a mating contact surface at an inner side of the cylinder sleeve.

A rotogravure printing machine has a shaft that rotates and a rotogravure cylinder sleeve for rotation with the shaft. An annular end plate connects to the shaft, and the end plate has a contact surface for contact with a mating contact surface at an inner side of the cylinder sleeve.

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.

The present application discloses an anilox roll having a liquid carry capacity. The anilox roll includes a support; and a liquid transfer layer on an outer surface of the support, the liquid transfer layer having a plurality of liquid transfer cells for carrying a liquid. The liquid carrying capacity of the anilox roll is adjustable.