Abstract: A bifilar winding system for the manufacture of poloidal field superconducting magnets for nuclear fusion includes two superconducting coil winding production lines which are symmetrically arranged, a dropping fixture, a rotary platform and a winding mold, and an automatic control system. Each of the two winding production lines includes a conductor unwinding device, a straightener, an ultrasonic cleaning machine, a sandblasting and cleaning machine, a bending machine, an inter-turn insulation taping machine. During the winding of a coil, a superconducting conductor is unwound by the conductor unwinding device under the control of the automatic control system, then straightened, ultrasonically cleaned, sandblasted and cleaned, and bent into a desired radius, then wrapped with multiple layers of insulating tape by the inter-turn insulation taping machine, and finally fixed, by the dropping fixture, precisely on the rotary platform at a correct position within a profile of the winding mold.

Abstract: The present invention discloses an inter-layer transition forming machine for winding of a large-sized superconducting coil. A vertically movable forming mechanism and a horizontally movable forming mechanism are mounted on a fixing plate. When the winding of a large-sized superconducting coil performs inter-layer transition, an armored superconducting conductor is clamped by wedge clamping mechanisms with right- and left-handed threads on the vertically movable forming mechanism and the horizontally movable forming mechanism, and a reference line on the conductor is ensured to be aligned with a reference line on a forming mold. The vertically movable forming mechanism is pressed down, under the drive of a double-acting hydraulic cylinder, in a vertical direction to form inter-layer transition, and the horizontally movable forming mechanism moves in a horizontal direction according to the reduction of the vertically movable forming mechanism.

Abstract: A feed-through ultrasonic cleaning system for winding of a superconducting coil, including a sealed chamber system, a main ultrasonic cleaning system, a deionized water spraying system, a compressed air blow-drying system, and an automatic control system. During the winding of an armored superconducting coil, a superconducting conductor which is fed at a constant speed successively passes through a sealed chamber, an ultrasonic cleaning chamber, a first compressed air blow-drying chamber, a deionized water spray chamber, and a second compressed air blow-drying chamber in the ultrasonic cleaning system.

Abstract: Disclosed is a bifilar winding system for the manufacture of poloidal field superconducting magnets for nuclear fusion, including two superconducting coil winding production lines which are symmetrically arranged, a dropping fixture, a rotary platform and a winding mold, and an automatic control system. Each of the two winding production lines includes a conductor unwinding device, a straightener, an ultrasonic cleaning machine, a sandblasting and cleaning machine, a bending machine, an inter-turn insulation taping machine. During the winding of a coil, a superconducting conductor is unwound by the conductor unwinding device under the control of the automatic control system, then straightened, ultrasonically cleaned, sandblasted and cleaned, and bent into a desired radius, then wrapped with multiple layers of insulating tape by the inter-turn insulation taping machine, and finally fixed, by the dropping fixture, precisely on the rotary platform at a correct position within a profile of the winding mold.

Abstract: The present invention discloses an inter-layer transition forming machine for winding of a large-sized superconducting coil. A vertically movable forming mechanism and a horizontally movable forming mechanism are mounted on a fixing plate. When the winding of a large-sized superconducting coil performs inter-layer transition, an armored superconducting conductor is clamped by wedge clamping mechanisms with right- and left-handed threads on the vertically movable forming mechanism and the horizontally movable forming mechanism, and a reference line on the conductor is ensured to be aligned with a reference line on a forming mold. The vertically movable forming mechanism is pressed down, under the drive of a double-acting hydraulic cylinder, in a vertical direction to form inter-layer transition, and the horizontally movable forming mechanism moves in a horizontal direction according to the reduction of the vertically movable forming mechanism.

Abstract: Disclosed is a circulating device for cooling and heating superconducting magnet components at controllable rate, including a liquid nitrogen tank and a vacuum container. A container for accommodating the superconducting magnet component is provided at an upper end of an interior of the vacuum container. First and second pipelines join and then connect to a top of the liquid nitrogen tank through a coiled pipe. A third pipeline and a first branch of a fourth pipeline join and then connect to an inlet of an electric heater. A PID closed loop for temperature control is provided at the electric heater. A main pipeline of the outlet pipeline of the electric heater is connected to an inlet of the container. A second branch of the fourth pipeline, an outlet pipeline of the container and a branch pipeline of the outlet pipeline of the electric heater communicate with atmosphere.

Abstract: A feed-through ultrasonic cleaning system for winding of a large-sized superconducting coil, including a sealed chamber system, a main ultrasonic cleaning system, a deionized water spraying system, a compressed air blow-drying system, an automatic control system. During the winding of an armored superconducting coil, a superconducting conductor which is fed at a constant speed successively passes through a sealed chamber, an ultrasonic cleaning chamber, a first compressed air blow-drying chamber, a deionized water spray chamber, and a second compressed air blow-drying chamber in the ultrasonic cleaning system. By integrating mechanical dynamic sealing, ultrasonic cleaning and automatic control, the present invention meets a special requirement of removing oil and completely cleaning the conductor during the winding of large-sized superconducting coils.

Abstract: Provided are a communication apparatus and a method therefor that are capable of executing a checksum attachment processing without increase of a circuit scale. A data generating unit (for example, a CPU) that forms a communication apparatus generates data, and stores the data in a memory. A checksum processor calculates a checksum for the data read from the memory, and writes the checksum into a predetermined position in the data stored in the memory. A data sending unit (for example, a transmission processor, a MAC processing circuit, and a PHY processing circuit) reads the data having the written checksum from the memory, and sends the data to a network.

Abstract: Provided are a communication apparatus and a method therefor that are capable of executing a checksum attachment processing without increase of a circuit scale. A data generating unit (for example, a CPU) that forms a communication apparatus generates data, and stores the data in a memory. A checksum processor calculates a checksum for the data read from the memory, and writes the checksum into a predetermined position in the data stored in the memory. A data sending unit (for example, a transmission processor, a MAC processing circuit, and a PHY processing circuit) reads the data having the written checksum from the memory, and sends the data to a network.

Abstract: A DMA transfer control device for controlling a DMA transfer between a source and a destination is provided. The DMA transfer control device has: a buffer in which a transfer data is stored; and a bus cycle generation unit performing a burst transfer of the transfer data between the buffer and the source or the destination. The bus cycle generation unit performs an undefined-length burst transfer until an access address reaches a burst address boundary in the source or the destination. The bus cycle generation unit performs a fixed-length burst transfer after the undefined-length burst transfer until transfer of the transfer data is completed.