Abstract: A ship cabin loading capacity measurement method and apparatus thereof, comprises: acquiring point cloud measurement data of a ship cabin; optimizing the point cloud measurement data according to a predetermined point cloud data processing rule, and generating optimized ship cabin point cloud data; calculating said ship cabin point cloud data with a predetermined loading capacity calculation rule, and getting ship cabin loading capacity data. According to the ship cabin loading capacity measurement method of the present invention, the point cloud measurement data can be acquired by a lidar, and processing the point cloud measurement data of the ship cabin with a predetermined point cloud data processing law and a computation law, and as the point cloud data processing law and the computation law can be deployed in a computer device in advance, after point cloud measurement data acquisition, loading capacity of a ship cabin can be acquired quickly and precisely.

Abstract: A condensation-recovery device for overpressure gas based on liquefied natural gas (LNG) cold energy, including a tank body and a condensation cavity provided on a bottom thereof. LNG is stored in the condensation cavity to condense boil-off gas (BOG). The condensation cavity includes a vertical hollow tube arranged in the tank body, and an engagement mechanism is provided on a bottom of the vertical hollow tube. The vertical hollow tube is configured such that the gas can experience preliminary contact with the LNG when flowing therein, and the gas will continuously enter the vertical hollow tube under the action of pressure difference. After entering the conical tube, the gas will be distributed along the cavity of the conical tube to spread downward, so as to increase a contact time of the gas and the LNG while avoiding expanding diffusion area of the gas after entering the LNG.

Abstract: A device for measuring volume of spherical tanks, includes a base, four supporting rods, a driving mechanism, a rotating disc and a counterweight mechanism. The base is provided with a first through hole and a circular fixing base with a second through hole. The supporting rods are circumferentially provided on the fixing base, with a sliding rod slidably provided at the lower side. An outer end of the sliding rod is provided with a limiting plate. The driving mechanism can drive the sliding rods to move simultaneously in radial directions. The rotating disc with a third through hole is arranged on the fixing base, and is rotatably provided with a reel around which a steel tape is wound. A free end of the steel tape is provided with a balancing disc whose opposite sides are provided with laser rangefinders. The counterweight mechanism can keep the balancing disc stable.

Abstract: A wall-climbing robot for measuring capacity of vertical metal tanks includes a robot body including a chassis, a casing, and wheels. The robot body further includes: an attraction unit including a plurality of magnets; a measurement unit including a bendable ruler provided on the chassis and protruding from a top of the casing; the rust removal unit including a rust removing bucket provided at a front side of the robot body, and a driver for the lifting and lowering of the rust removing bucket; and a control unit including a microcontroller, a posture detector, an obstacle detector, an attraction detector, and a distance sensor. The wall-climbing robot of the present invention leaves no indentation on a surface of the metal tank, and is not affected by the rusts formed on the surface.

Abstract: A moving device for a three-dimensional scanner, including a main body, a moving mechanism, a round tube, a driving mechanism and a fixing mechanism. A connecting rod is vertically fixed on an upper side of the main body. The moving mechanism is configured to drive the main body to move. The round tube is sleevedly provided on an outer side of the connecting rod. A fixing sleeve is vertically fixed on an inner side wall of the round tube. A sliding rod is insertedly provided in the fixing sleeve. A lower end of the sliding rod is fixedly connected to the main body, and an upper end extends to be below the 3D scanner and is provided with a top plate. When the round tube moves upward to an outer side of the 3D scanner, the round tube is fixed by the fixing mechanism.

Abstract: A moving device for a three-dimensional scanner, including a main body, a moving mechanism, a round tube, a driving mechanism and a fixing mechanism. A connecting rod is vertically fixed on an upper side of the main body. The moving mechanism is configured to drive the main body to move. The round tube is sleevedly provided on an outer side of the connecting rod. A fixing sleeve is vertically fixed on an inner side wall of the round tube. A sliding rod is insertedly provided in the fixing sleeve. A lower end of the sliding rod is fixedly connected to the main body, and an upper end extends to be below the 3D scanner and is provided with a top plate. When the round tube moves upward to an outer side of the 3D scanner, the round tube is fixed by the fixing mechanism.

Abstract: The invention provides an oil tank measurement method and system based on laser point cloud analysis, comprising: acquiring point cloud data inside an oil tank, which is collected by a laser measurement device; separating point cloud data of a main body of the oil tank from point cloud data of a plug, to acquire the point cloud data of the main body of the oil tank; calculating, based on Gauss mapping, an axis for the point cloud data of the main body of the oil tank; determining any one first plane perpendicular to the axis, and projecting a point cloud of the main body onto the first plane to obtain a point cloud of a projected cross-section of the tank body on the first plane; multi-segment fitting the point cloud of the projected cross-section of the tank body; and calculating a volume according to a result of multi-segment fitting.

Abstract: A ship cabin loading capacity measurement method and apparatus thereof, comprises: acquiring point cloud measurement data of a ship cabin; optimizing the point cloud measurement data according to a predetermined point cloud data processing rule, and generating optimized ship cabin point cloud data; calculating said ship cabin point cloud data with a predetermined loading capacity calculation rule, and getting ship cabin loading capacity data. According to the ship cabin loading capacity measurement method of the present invention, the point cloud measurement data can be acquired by a lidar, and processing the point cloud measurement data of the ship cabin with a predetermined point cloud data processing law and a computation law, and as the point cloud data processing law and the computation law can be deployed in a computer device in advance, after point cloud measurement data acquisition, loading capacity of a ship cabin can be acquired quickly and precisely.

Abstract: A wall-climbing robot for measuring capacity of vertical metal tanks includes a robot body including a chassis, a casing, and wheels. The robot body further includes: an attraction unit including a plurality of magnets; a measurement unit including a bendable ruler provided on the chassis and protruding from a top of the casing; the rust removal unit including a rust removing bucket provided at a front side of the robot body, and a driver for the lifting and lowering of the rust removing bucket; and a control unit including a microcontroller, a posture detector, an obstacle detector, an attraction detector, and a distance sensor. The wall-climbing robot of the present invention leaves no indentation on a surface of the metal tank, and is not affected by the rusts formed on the surface.

Abstract: The invention provides an oil tank measurement method and system based on laser point cloud analysis, comprising: acquiring point cloud data inside an oil tank, which is collected by a laser measurement device; separating point cloud data of a main body of the oil tank from point cloud data of a plug, to acquire the point cloud data of the main body of the oil tank; calculating, based on Gauss mapping, an axis for the point cloud data of the main body of the oil tank; determining any one first plane perpendicular to the axis, and projecting a point cloud of the main body onto the first plane to obtain a point cloud of a projected cross-section of the tank body on the first plane; multi-segment fitting the point cloud of the projected cross-section of the tank body; and calculating a volume according to a result of multi-segment fitting.