A pedestal bearing that has a pedestal bearing housing with a bearing seat, a cooling duct system with at least one cooling duct, and an anti-friction bearing arranged in the bearing seat and has an anti-friction bearing outer ring. The bearing seat has a first inner circumferential side. The pedestal bearing housing has a first contact surface and is configured to transmit a bearing force (F) from the anti-friction bearing outer ring to the first contact surface. The cooling duct extends circumferentially and is configured to conduct a coolant, which can be fed into the cooling duct in order to cool the anti-friction bearing and/or the pedestal bearing housing. The first inner circumferential side of the bearing seat of the pedestal bearing housing delimits the cooling duct radially on the outside and the anti-friction bearing outer ring delimits the cooling duct radially on the inside.

A roll for continuous casting comprises a cylindrical roll rotatably mounted on a fixed axle and having a cooling chamber that surrounds the axle for receiving a flow of coolant. The axle is mounted on a roll support system. The roll support system comprises a first roll support connected to a coolant supply system and a second roll support connected to a coolant drain system. The axle comprises a first inlet connected to the first roll support, a first outlet connected to the coolant chamber, a second inlet connected to the coolant chamber, and a second outlet connected to the second roll support. A coolant flow circuit has a flow path from the coolant supply system to the coolant drain system through the first roll support, the first inlet, the first outlet, the coolant chamber, the second inlet, the second outlet, and the second roll support.

A six-high rolling (also known as sexto) mill stand that is suited for hot rolling an intermediate strip into a thin strip that is less than 0.8 mm thick. A combined casting and rolling installation that includes the six-high rolling mill stand allowing for hot rolling in long uninterrupted sequences, without any change of the work rolls to obtain a strip with good geometry due to moderate rolling forces.

Using an apparatus for manufacturing a thin steel sheet including the followings which are arranged in order: a continuous casting machine (1) for a thin slab having a slab thickness of 70 mm to 120 mm at a lower end of a mold; a holding furnace (2) that is configured to maintain a temperature of a cast slab (10) and/or heats the cast slab (10); and a rolling stand (3) by which finish rolling is performed, the casting speed of the thin slab is set to 4 to 7 m/min, the slab (10) is reduced at a rolling reduction of 30% or more by the reduction roll (4) after solidification is completed and when a center temperature of the slab is 1300 C. or higher, and the slab (10) is held at a temperature of 1150 C. or higher and 1300 C. or lower for five minutes or longer in the holding furnace (2).

A back-up roll device and method for conducting corner deformation on a chamfered continuous casting slab. The back-up roll device includes back-up rolls with -angle bevels, movable bearing seats, bearing seat moving rails, bearing seat motion holding mechanisms and inner arc or outer arc frames of a casting machine. The back-up rolls are arranged on the inner and/or outer arc frames of the horizontal segment of the casting machine. Support surfaces of the back-up rolls make contact with and squeeze smaller obtuse angles adjacent to the wide face of the inner or outer arc on the chamfered continuous casting slab, and therefore each smaller obtuse angle is squeezed into two larger obtuse angles. The back-up roll device and method for conducting corner deformation on the chamfered casting slab can achieve the purposes of eliminating edge slivers.

Guide roller including a bearing journal at each of two ends. Each bearing journal is provided with a plain bearing designed as a hollow journal, and can be connected to the coolant supply line to conduct coolant through the hollow journal into or out of the coolant channel. The plain bearing is lubricated by coolant conducted through the bearing journal. A roller assembly for a strand casting system is provided with a plurality of guide rollers. The guide rollers are arranged at an axial distance from each other along a strand produced by the strand casting system and are each rotatably supported in a respective bearing mount. Each bearing mount is arranged on at least one frame part in a preloaded manner The bearing mounts are supported on the frame parts so as to be self-setting by elastically pliable connecting structure.

An R, R, C method and equipment for continuously casting amorphous, ultra-microcrystalline, microcrystalline and the like, metal profiles is provided. A working chamber of an exhaust hood with a powerful exhaust hood, and a working cold source of liquid nitrogen at a temperature of t=190 C. and a pressure of p=1.877 bar are used. The working chamber of exhaust hood is located at the outlet of hot mold, and only air is contained therein in addition to slabs or profiles that are pulled out, without any device or equipment. A traction mechanism pulls metal slabs or profiles out from the outlet of cross section of hot mold. A liquid nitrogen ejector ejects liquid nitrogen to the metal slabs or profiles of different brands and specifications at a liquid nitrogen ejection volume of liquid nitrogen V, an ejection speed of liquid nitrogen K and a thickness of liquid nitrogen ejection layer h.

A cooled strand guide roller (1) mounted at more than one location for guiding a metal strand (S) in a continuous casting machine, and a method for cooling a strand guide roller (1) mounted at more than one location. An internally cooled strand guide roller (1) is mounted at more than one location. The height of the strand guide roller (1) is intended to be adjustable easily and quickly. The strand guide roller (1) has a collecting bar (7) for supplying the strand guide roller (1) with cooling water. The collecting bar (7) includes a plurality of brackets (10, 10a, 10b). Between two successive brackets (10, 10a, 10b), there is at least one coolant pipe (11) for fluidically connecting the brackets (10, 10a, 10b). An outer bracket (10a) has at least one first connection (8) for internal cooling of the cooled strand guide roller (1) and at least one second connection (9) for cooling the bearing blocks (4). The first connection (8) is fluidically connected to the ducts (3) of the individual rollers (2a, 2b) and the second connection (9) is fluidically connected to the bearing blocks (4) via the brackets (10).

A surface layer material of a hot rolling mill roll is provided. The surface layer has a chemical composition containing, by mass %, C: 2.4% or more and 3.5% or less, Si: 1.2% or more and 2.4% or less, Mn: 0.2% or more and 2.0% or less, Cr: 0.8% or more and 2.1% or less, Mo: 0.3% or more and 1.1% or less, Ni: 3.0% or more and 6.0% or less, V: 1.0% or more and 2.2% or less, Nb: 0.1% or more and 0.5% or less, REM: 0.0005%) or more and 0.1% or less, Al: 0.003% or more and 0.05% or less, and the balance being Fe and inevitable impurities. The contents of C, Cr, V, Nb, REM, and Al satisfy the relationships Cr+0.2C(0.24V+0.13Nb)3.0 and 0.01REM/Al3.2.

An alloy cast strip preparation method includes a melting process and a casting cooling process. The melting process includes controlling a power of an induction melting furnace to perform a cyclic heat treatment to completely melt an alloy raw material before a surface temperature of a melt obtained by melting the alloy raw material is raised to 1300 C., and, after the alloy raw material is melted, adjusting the power of the induction melting furnace to stabilize the surface temperature of the melt at a temperature in a range from 1400 C. to 1500 C. The casting cooling process includes performing casting cooling on the melt arranged on a surface of a rotary cooling roll to obtain an alloy cast strip while controlling a surface linear velocity of the rotary cooling roll to be from 1.5 m/s to 2.25 m/s.