What is provided is a novel and improved dross removal device capable of more efficiently collecting a bath surface dross using a dross robot, and a dross removal method.

In order to solve the problem, according to an aspect of the present invention, there is provided a dross removal device including: a dross robot that is configured to collect a bath surface dross present on a bath surface of a coating bath; a dross sensor that is configured to measure an intensity of infrared light from the bath surface of the coating bath; a dross sensor control device that is configured to specify a position of the bath surface dross according to a temporal change amount in the intensity of the infrared light; and a dross robot control device that is configured to cause the dross robot to collect the bath surface dross at the position specified by the dross sensor control device.

A method for manufacturing a high-efficiency protective paper having functions of heat dissipation, heat conduction and electromagnetic absorption is disclosed herein. It comprises the steps of providing a thermal conductive composite to a substrate, wherein the thermal conductive composite is made by fully mixing a metal salt and a nano-scale magnetic metal oxide; evenly distributing the thermal conductive composite over the substrate to form a hybrid material; leveling and rolling the hybrid material to form a protective paper having a dense structure; and receiving and vacuum heating the protective paper.

A method for manufacturing a high-efficiency protective paper having functions of heat dissipation, heat conduction and electromagnetic absorption is disclosed herein. It comprises the steps of providing a thermal conductive composite to a substrate, wherein the thermal conductive composite is made by fully mixing a metal salt and a nano-scale magnetic metal oxide; evenly distributing the thermal conductive composite over the substrate to form a hybrid material; leveling and rolling the hybrid material to form a protective paper having a dense structure; and receiving and vacuum heating the protective paper.

A gas wiping device for controlling a thickness of a coating layer deposited on a running metal strip plated with molten metal in an industrial hot-dip installation includes: a main nozzle unit and a secondary nozzle unit, for blowing a wiping jet on a surface of the running strip, the main nozzle unit and secondary nozzle unit respectively including a main and secondary chamber fed by pressurized non-oxidizing gas and at least a main and secondary elongated nozzle slot formed in a tip of the respective main and secondary nozzle units, the tips each including an external top side, facing a downstream side of the running strip, and making an angle with the surface of the running strip. The secondary nozzle unit is adjacent the main nozzle unit over an external top side of the main nozzle unit tip.

An impregnator for impregnating a fabric layer comprising: a chamber, the chamber being structured and arranged so as to retain a binding composition in a fluid state; a first opening being structured and arranged so as to allow the fabric layer entering the chamber in a dry state from a top portion of the chamber to be dived into the binding composition; and a second opening extending along the longitudinal axis of a bottom portion of the chamber, the second opening being structured and arranged to allow the fabric layer to exit from the bottom portion of the chamber in an impregnated state, the second opening comprising a first lip structured and arranged to be in contact with a first surface of the fabric layer and a second lip structured and arranged to be in contact with a second surface of the fabric layer.

An alternating pressure melt impregnation device and a melt impregnation method, including having a resin melt squirted from each resin melt runner on an upper die and a lower die of a melt injection area, and thus the squirted resin melt is enable to be squirted directly on an upper surface and a lower surface of a continuous fiber bundle which is entering into an impregnation chamber. Impregnation and infiltration for both surfaces of the continuous fiber bundle are primarily completed by a squirted pressure. The resin melt inside the impregnation chamber flows to a decompression chambers at both sides of the impregnation chamber. When the resin melt flows to a throttle plate, a re-impregnation for the continuous fiber bundle is realized. Then the pressure is decreased and a section of the resin melt is enlarged and a radial flow is generated due to the Barus effect.

A short stress path-type electrode sheet rolling machine and an integrated machine equipment for manufacturing lithium battery electrode sheets, whereby the rolling machine comprises: an upper roller mechanism, a lower roller mechanism, an upper bearing base, a lower bearing base and a roller-gap adjusting mechanism; the upper roller mechanism is connected to the upper bearing base, and the lower roller mechanism is connected to the lower bearing base; the upper bearing base and the lower bearing base are connected by means of a guide shaft; the roller-gap adjusting mechanism is connected to the upper roller mechanism so as to adjust a roller gap between the upper roller mechanism and the lower roller mechanism. The rolling machine has a simpler and more reliable structure, has a shorter stress return path when performing electrode sheet rolling, and may improve rolling precision and rolling quality.

The present invention relates to a method for manufacturing an aerogel sheet and comprises: a step (a) of impregnating an acid solution into a fiber sheet to clean the fiber sheet by using the acid solution and impregnating a binder solution into the fiber sheet that is cleaned by using the acid solution to manufacture a pre-processed fiber sheet; a step (b) of impregnating a silica precursor into the pre-processed fiber sheet; and a step (c) of a gelling catalyst into the fiber sheet into which the silica precursor is impregnated to gelate the silica precursor.

Carbon nanotube threads are coated with a coating solution such as dimethylformamide (DMF), ethylene glycol (EG), polyethylene glycol (PEG), PEG200 (PEG with an average molecular weight of approximately 200 grams per mole (g/mol)), PEG400 (PEG with an average molecular weight of approximately 400 g/mol), aminopropyl terminated polydimethylsiloxane (DMS 100 cP),polymide, poly(methylhydrosiloxane), polyalkylene glycol, (3-aminopropyl)trimethoxysilane, hydride functional siloxane O resin, platinum (0) -1,3-divinyl-1,1,3,3-tetramethyl-disiloxane, moisture in air, acetic acid, water, poly(dimethylsiloxane) hydroxy terminated, (3-glycidyloxypropyl)-trimethoxysilane or a combination thereof. The coated carbon nanotubes may be used to stitch in a Z-direction into a composite such as a polymer prepreg to strengthen the composite. The stitching may occur using a sewing machine.

A bare optical fiber coating device includes: a nipple having a nipple hole through which a bare optical fiber is inserted vertically from above; an intermediate die that has an intermediate die hole through which the bare optical fiber passing through the nipple hole is inserted and that is disposed vertically below the nipple; a first coating die that has a first coating die hole through which the bare optical fiber passing through the intermediate die hole is inserted and that is provided vertically below the intermediate die; and a first resin circulation chamber that is formed by the nipple and the intermediate die, is formed between the nipple hole and the intermediate die hole in an annular shape surrounding the bare optical fiber passing through the nipple hole, and is configured to circulate liquid resin.