Abstract: An ultrasonic flaw detection device includes: a matrix array probe; an ultrasonic wave transmitting and receiving unit that controls the matrix array probe; and an evaluation unit that detects a planar defect based on the reflected ultrasonic waves received by the ultrasonic wave transmitting and receiving unit. The matrix array probe has a plurality of vibration elements arranged lattice-like, an array pitch of the vibration elements in the pipe axis direction is larger than a wavelength of ultrasonic waves transmitted and received, widths of the vibration elements in the pipe axis direction decrease outward in the pipe axis direction from a pipe axis direction center position of the matrix array probe, and the widths and center coordinates of the vibration elements in the pipe axis direction have been adjusted such that all of ultrasonic waves from the vibration elements overlap in a focal position control range for the ultrasonic waves.

Abstract: An ultrasonic flaw detection device includes: a matrix array probe; an ultrasonic wave transmitting and receiving unit that controls the matrix array probe; and an evaluation unit that detects a planar defect based on the reflected ultrasonic waves received by the ultrasonic wave transmitting and receiving unit. The matrix array probe has a plurality of vibration elements arranged lattice-like, an array pitch of the vibration elements in the pipe axis direction is larger than a wavelength of ultrasonic waves transmitted and received, widths of the vibration elements in the pipe axis direction decrease outward in the pipe axis direction from a pipe axis direction center position of the matrix array probe, and the widths and center coordinates of the vibration elements in the pipe axis direction have been adjusted such that all of ultrasonic waves from the vibration elements overlap in a focal position control range for the ultrasonic waves.

Abstract: A line pipe having a wall thickness of 20 mm or more and a tensile strength of 560 MPa or more and a production method therefor are provided. The base metal portion contains particular amounts of C, Si, Mn, P, S, Al, Nb, Ca, N, and O, one or more component selected from Cu, Ni, Cr, Mo, V, and Ti as optional components, and the balance being Fe and unavoidable impurities. The microstructure in the pipe thickness direction contains 90% or more bainite and 1% or less of MA in a region that extends from a position 2 mm from an inner surface to a position 2 mm from an outer surface. In a hardness distribution in the pipe thickness direction, the hardness in a region other than a center segregation area is 220 Hv10 or less and the hardness in the center segregation area is 250 Hv10 or less.

Abstract: A line pipe and a production method therefor are provided. The microstructure in the pipe thickness direction contains 90% or more bainite in a region that extends from a position 2 mm from an inner surface to a position 2 mm from an outer surface. In a hardness distribution in the pipe thickness direction, the hardness in a region other than a center segregation area is 220 Hv10 or less and the hardness in the center segregation area is 250 Hv0.05 or less. The major axes of pores, inclusions, and inclusion clusters that are present in a portion that extends from a position 1 mm from the inner surface to a 3/16 position of the tube thickness and in a portion that extends from a position 1 mm from the outer surface to a 13/16 position of the tube thickness in the tube thickness direction are 1.5 mm or less. A continuous casting slab having the above-described composition is hot-rolled under particular conditions and then subjected to accelerated cooling.

Abstract: A welded steel pipe with excellent welded heat-affected zone toughness includes a butt weld formed by prior welding either an inner surface or an outer surface with a single layer for each of the inner and outer surfaces, wherein in the metallographic structure of a welded heat-affected zone, the martensite-austenite constituent (MA) area fraction is 4% or less, the average prior-austenite grain size is 400 ?m or less, and the following items are taken into account: the average prior-austenite grain size of a welded heat-affected zone formed by prior welding, the average prior-austenite grain size of a welded heat-affected zone formed by subsequent welding, the bead width determined at a position 5 mm apart from the tip of a weld bead formed by subsequent welding, the fusion line tilt angle of a weld bead of prior welding, and the fusion line tilt angle of a weld bead of subsequent welding.