Abstract: The present invention relates to a pigment paint for an exterior material and to a method for manufacturing the same. The pigment paint comprises: a flake matrix, a first metal oxide layer coated on the upper portion of the transparent matrix, an oxide layer containing MgO—SiO2 coated on the upper portion of the first metal oxide layer, and a second metal oxide layer coated on the upper portion of the oxide layer. In order to ensure humidity resistance and weather resistance required for a lustrous pigment paint for exterior materials, a cerium layer and an aluminum oxide layer are further coated. Properties such as high luminance, high chromaticity, and high gloss, which could not be achieved using conventional techniques, can be achieved and a pigment paint having a multi-colored pearl luster can be provided.

Abstract: The present invention relates to a nacreous pigment and a method of preparing the same. The nacreous pigment includes a flake substrate, a first metal oxide layer coated on the substrate, and an oxide layer coated on the first metal oxide layer and containing MgO.SiO2, and a second metal oxide layer coated on the oxide layer. The pigment exhibits high brightness, high chroma, high gloss, and multi-color effects.

Abstract: A robot system includes a supply station. The system further includes: a robot, a robot tank adapted to store a liquid and disposed at the robot; and a supply station configured to supply additional liquid to the tank.

Abstract: A system for returning a robot to a charger includes: a homing signal transmitter, including at least first, second, and third signal transmitters, each adapted to be provided at a front side of the charger and to respectively transmit signals which are different from each other in at least one of a code and a transmission distance, and a fourth signal transmitter, adapted to be provided on at least one lateral side of the charger and to transmit a signal which is different from the signals of the first, second, and third transmitters in code; a homing signal receiver provided at the robot and to receive at least one signal transmitted from the homing signal transmitter; and a controller adapted to identify the at least one signal and to control the robot to return to the charger based at least in part on the at least one signal.

Abstract: A robot cleaner system and a method for the robot cleaner to return to an external recharging apparatus. The robot cleaner system has an external recharging apparatus including a charging stand having a charging terminal, and a plurality of transmission parts for sending signals having different codes and strengths; a robot cleaner including a rechargeable battery, a connection terminal for connection with the charging terminal to supply power to the rechargeable battery, a receiving part for receiving signals from the plurality of transmission parts, and a control part for controlling a movement of the robot cleaner using the signals received by the receiving part, so that the connection terminal is connected to the charging terminal.

Abstract: A coordinates compensation method of a robot cleaner using an angle sensor compensates coordinates of the robot cleaner with reference to absolute coordinates of a recharging station, so as to improve robot cleaner's path following. The robot cleaner is in a standby mode at the recharging station, and moves to an operation area to perform a given job. The robot cleaner stops the given job upon determining an accumulative angle exceeding a predetermined level, and returns to the recharging station. Current coordinates of the robot cleaner are aligned with reference coordinates of the recharging station, and the robot cleaner moves to a previous spot where it was before it returns to the recharging station, and resumes the work from where it stopped.

Abstract: A method of compensating a gyro sensor of a robot cleaner is provided. The method includes changing to a compensation mode if a robot cleaner travels greater than a compensation reference, and compensating an output value of the gyro sensor by use of an upper camera.

Abstract: Disclosed is a mobile robot system having a plurality of exchangeable work modules, thereby providing a mobile robot capable of performing various functions at a low cost. The mobile robot system comprises a plurality of work modules, which perform different works, respectively; a module station for connecting the plurality of work modules; and a mobile robot, which selects and connects to one of the plurality of work modules from the module station according to a work task to be performed. The mobile robot autonomously operates to perform the work task.

Abstract: A robot system includes a supply station. The system further includes: a robot, a robot tank adapted to store a liquid and disposed at the robot; and a supply station configured to supply additional liquid to the tank.

Abstract: A system for returning a robot to a charger includes: a homing signal transmitter, including at least first, second, and third signal transmitters, each adapted to be provided at a front side of the charger and to respectively transmit signals which are different from each other in at least one of a code and a transmission distance, and a fourth signal transmitter, adapted to be provided on at least one lateral side of the charger and to transmit a signal which is different from the signals of the first, second, and third transmitters in code; a homing signal receiver provided at the robot and to receive at least one signal transmitted from the homing signal transmitter; and a controller adapted to identify the at least one signal and to control the robot to return to the charger based at least in part on the at least one signal.

Abstract: A mobile robot system includes: a mobile robot; a station configured to accommodate the mobile robot; a call connection unit provided at the home station and configured to receive a call; and a call signal conversion unit configured to convert the call into a control signal and to transmit the control signal to the mobile robot.

Abstract: In exemplary embodiments, a robot cleaner with improved safety features comprises a driving part for movably supporting a cleaner body and supplying a driving force for operating the cleaner body; a suction part mounted on the cleaner body to draw in dust from a surface being cleaned; a body sensor mounted on the cleaner body to perceive any approach or contact of at least a part of human body or pet; and a control part for turning on and off the driving part according to a signal detected by the body sensor.

Abstract: A robot cleaner that includes a driving unit for driving a plurality of wheels, a transmitter/receiver for communicating with an external charger, and a controller for controlling the driving unit. The controller controls the transmitter/receiver to communicate with the external charger while traveling an area to be cleaned and stores at least one location of communication in a memory. The controller further controls the driving unit to cause the robot cleaner to travel to the external charger using at least one location of communication.

Abstract: A robot vacuum cleaner that comprises a driving unit moving a body on a cleaning surface; a cleaning area detecting unit detecting an area of the cleaning surface; and a central processing unit calculating a spiral cleaning travel pattern corresponding to a shape of each cleaning area based on the information detected by the cleaning area detecting unit to output a cleaning travel signal corresponding the calculated cleaning travel pattern to the driving unit. The cleaning travel pattern can be variable applied depending on a shape of each cleaning area such that the coverage ratio of the cleaning area can increase.

Abstract: A mobile robot capable of humidifying an entire room. The mobile robot comprises a driving part for movably supporting a body and providing a driving force to move the body, a humidifier disposed on the body; and a controller for controlling the driving part.

Abstract: An automatic cleaning apparatus has a cleaner body having at least one driving wheel, and in certain disclosed embodiments, a vapor spray means installed in the cleaner body for generating water vapor during operation, and spraying the generated water vapor toward a lower part of the cleaner body.

Abstract: A robot vacuum cleaner has a driving unit moving a cleaner body on a cleaning surface; a distance detecting unit detecting a distance of travel by the driving unit; an obstacle detecting unit detecting an obstacle near the cleaner body; and a central processing unit moving the cleaner body to a location a certain distance away from the obstacle according to a cleaning travel pattern when the obstacle detecting unit detects an obstacle, and variably applying the distance as the obstacle is detected and outputting a travel signal to the driving unit, thereby evenly covering the cleaning area.

Abstract: A robot control system and a robot control method provide improved user convenience in operating the system. The robot control system includes a wireless IP sharing device, connected with the Internet, for transmitting and receiving an image signal and/or a control signal, a robot running by itself in accordance with a command received through the wireless IP sharing device, and performing a designated job, the robot being installed with a wireless communication module, a portable wireless terminal having a motion sensor, for wirelessly transmitting an operation command to the wireless communication module, or receiving image signal and/or control signal, and a robot server, connected with the Internet, for outputting a control screen of the robot, and the image signal and/or the control signal which is received from the robot, to the portable wireless terminal. The robot is controlled by use of the motion sensor installed at the portable wireless terminal.

Abstract: A robot cleaner system and a method for the robot cleaner to return to an external recharging apparatus. The robot cleaner system has an external recharging apparatus including a charging stand having a charging terminal, and a plurality of transmission parts for sending signals having different codes and strengths; a robot cleaner including a rechargeable battery, a connection terminal for connection with the charging terminal to supply power to the rechargeable battery, a receiving part for receiving signals from the plurality of transmission parts, and a control part for controlling a movement of the robot cleaner using the signals received by the receiving part, so that the connection terminal is connected to the charging terminal.

Abstract: A coordinates compensation method of a robot cleaner using an angle sensor compensates coordinates of the robot cleaner with reference to absolute coordinates of a recharging station, so as to improve robot cleaner's path following. The robot cleaner is in a standby mode at the recharging station, and moves to an operation area to perform a given job. The robot cleaner stops the given job upon determining an accumulative angle exceeding a predetermined level, and returns to the recharging station. Current coordinates of the robot cleaner are aligned with reference coordinates of the recharging station, and the robot cleaner moves to a previous spot where it was before it returns to the recharging station, and resumes the work from where it stopped.