Abstract: A heating device provides heat for heating in various modes, such as an air flow direction control mode, a radiant heat specialized mode, and a convective heat specialized mode, through rotation of thermally conductive plates depending on user's requirements, thereby increasing user satisfaction. The thermally conductive plates increase heating efficiency by ensuring thermal efficiency according to a mode corresponding to the purpose of use.

Abstract: A method of calculating a collision risk of a ship according to an embodiment of the present disclosure may include: calculating an available velocity area based on maneuvering performance of a host ship; calculating a velocity obstacle area where there is a possibility of collision between an object and the host ship; and calculating a collision risk based on at least one of the available velocity area, the velocity obstacle area, and a preset weight.

Abstract: A positive electrode active material includes a nickel-based lithium composite metal oxide having a Ni content of 80 atm % or greater among transition metals except lithium, and in the form of a single particle or pseudo-single particle. The nickel-based lithium composite metal oxide has a coating layer positioned on the surface thereof, wherein the coating layer contains cobalt. The positive electrode active material also satisfies [Equation 1] 1?XY/Z?3, wherein X is the molar number (mol %) of Co in the coating layer based on 100 moles of the nickel-based lithium composite metal oxide, Y is the average particle diameter (?m) of nodules of the nickel-based lithium composite metal oxide, and Z is D50 (?m) of the positive electrode active material, wherein Z is from 5 ?m to 12 ?m.

Abstract: A flow nanoparticle measurement device according to an embodiment of the present disclosure includes a flow cell in which a liquid sample flows, a first laser beam being irradiated to the flow cell; a laser generator configured to generate the first laser beam; and a flow controller configured to control a flow of the liquid sample for the flow cell.

Abstract: A positive electrode active material includes a nickel-based lithium composite metal oxide having a Ni content of 80 atm % or greater among transition metals except lithium, and in the form of a single particle or pseudo-single particle. The nickel-based lithium composite metal oxide has a coating layer positioned on the surface thereof, wherein the coating layer contains cobalt. The positive electrode active material also satisfies [Equation 1] 1?XY/Z?3, wherein X is the molar number (mol %) of Co in the coating layer based on 100 moles of the nickel-based lithium composite metal oxide, Y is the average particle diameter (?m) of nodules of the nickel-based lithium composite metal oxide, and Z is D50 (?m) of the positive electrode active material, wherein Z is from 5 ?m to 12 ?m.

Abstract: A positive electrode active material includes a nickel-based lithium composite metal oxide having a Ni content of 80 atm % or greater among transition metals except lithium, and in the form of a single particle or pseudo-single particle. The nickel-based lithium composite metal oxide has a coating layer positioned on the surface thereof, wherein the coating layer contains cobalt. The positive electrode active material also satisfies [Equation 1] 1?XY/Z?3, wherein X is the molar number (mol %) of Co in the coating layer based on 100 moles of the nickel-based lithium composite metal oxide, Y is the average particle diameter (?m) of nodules of the nickel-based lithium composite metal oxide, and Z is D50 (?m) of the positive electrode active material, wherein Z is from 5 ?m to 12 ?m.

Abstract: A flow nanoparticle measurement device according to an embodiment of the present disclosure includes a flow cell configured to form a flow path through which a liquid sample flows, a laser generator configured to generate a first laser beam and irradiate the first laser beam to the flow cell, a plurality of detectors disposed in the flow cell and configured to detect a shock wave of a plasma generated in the flow cell by the first laser beam and generate a detection signal, and a controller configured to obtain the detection signal from the plurality of detectors and determine a type and a size of nanoparticles contained in the liquid sample in response to the detection signal.

Abstract: A flow nanoparticle measurement device according to an embodiment of the present disclosure includes a flow cell configured to form a flow path through which a liquid sample flows, a laser generator configured to generate a first laser beam and irradiate the first laser beam to the flow cell, a plurality of detectors disposed in the flow cell and configured to detect a shock wave of a plasma generated in the flow cell by the first laser beam and generate a detection signal, and a controller configured to obtain the detection signal from the plurality of detectors and determine a type and a size of nanoparticles contained in the liquid sample in response to the detection signal.

Abstract: A flow nanoparticle measurement device according to an embodiment of the present disclosure includes a flow cell in which a liquid sample flows, a first laser beam being irradiated to the flow cell; a laser generator configured to generate the first laser beam; and a flow controller configured to control a flow of the liquid sample for the flow cell.

Abstract: A flow cell according to an embodiment of the present disclosure includes a main flow portion configured to extend from one end in one direction and lead to other end, a pulsed laser beam being irradiated to the main flow portion, the main flow portion including a flow space in which a liquid sample flows; an inlet guide portion connected to the main flow portion in a different direction from the one direction and configured to guide an introduction of the liquid sample into the main flow portion; and an outlet guide portion connected to the main flow portion in a different direction from the one direction and configured to guide a discharge of the liquid sample from the main flow portion.

Abstract: A liquid crystal composition including about 70 percent by weight to about 98 percent by weight of a liquid crystal molecule; and about 2 percent by weight to about 30 percent by weight of a hydrogel agent, each based on a total weight of the liquid crystal composition.