Aluminum alloy sheet for battery lid use having suitable strength and excellent in formability and work softenability, which aluminum alloy sheet for battery lid use enabling formation of an integrated explosion-proof valve with little variation in operating pressure and excellent in cyclic fatigue resistance, and a method of production of the same are provided, the aluminum alloy sheet for battery lid use for forming an integrated explosion-proof valve having a component composition containing Fe: 1.05 to 1.50 mass %, Mn: 0.15 to 0.70 mass %, Ti: 0.002 to 0.15 mass %, and B: less than 0.04 mass %, having a balance of Al and impurities, having an Fe/Mn ratio restricted to 1.8 to 7.0, restricting, as impurities, Si to less than 0.40 mass %, Cu to less than 0.03 mass %, Mg to less than 0.05 mass %, and V to less than 0.03 mass %, having a tensile strength of 95 MPa or more, having a value of elongation of 40% or more, having a recrystallized structure, having a value of (TS95TS80) of less than 3 MPa when defining a tensile strength after cold rolling by a rolling reduction of 80% as TS80 and defining a tensile strength after cold rolling by a rolling reduction of 95% as TS95, and having a value of elongation after cold rolling by a rolling reduction of 90% of 5.0% or more. Furthermore, an average grain size of the recrystallized grains of the recrystallized structure is preferably 15 to 30 m.

A device for determining orientation of an object, including a measurement body, which reflects electromagnetic radiation and can be brought into physical contact with a surface of the object to determine the orientation. The device includes: a measurement carriage movable along the object during the determination of the orientation and which has a sliding surface that can be brought into physical contact with the object; a retaining unit which retains the measurement body and is connected to the measurement carriage so as to be pivotable between a maximal position, in which the measurement body protrudes beyond the sliding surface on the object side, and a minimal position, in which the measurement body does not protrude beyond the sliding surface on the object side; and a restoring device that applies a force to the retaining unit toward the maximal position.

A monitoring and control system is for a strand guide roll assembly of a continuous casting machine which includes a plurality of rolls spaced apart generally along a path of travel of a strand from an input end located adjacent to a mold to an output end. The system includes a plurality of sensors each coupled with a separate one of the rolls so as to be spaced apart generally along the travel path, each sensor senses magnitude of a load on the coupled roll. A logic circuit is coupled with each sensor so as to receive input from the sensors corresponding to load magnitude. The logic circuit is configured to determine from the sensor input a general position on the travel path at which the strand substantially solidifies, preferably by calculating a difference between loads on adjacent rolls and determining when the difference is less than a predetermined value.

A monitoring and control system is for a strand guide roll assembly of a continuous casting machine which includes a plurality of rolls spaced apart generally along a path of travel of a strand from an input end located adjacent to a mold to an output end. The system includes a plurality of sensors each coupled with a separate one of the rolls so as to be spaced apart generally along the travel path, each sensor senses magnitude of a load on the coupled roll. A logic circuit is coupled with each sensor so as to receive input from the sensors corresponding to load magnitude. The logic circuit is configured to determine from the sensor input a general position on the travel path at which the strand substantially solidifies, preferably by calculating a difference between loads on adjacent rolls and determining when the difference is less than a predetermined value.

Disclosed is a continuous casting ingot mold for metals, of the type made of an assembly of metal plates mounted against cooling devices configured to allow cooling of the metal plates by the circulation of a liquid coolant. Said ingot mold comprises an optical fiber with a diameter greater than 1.6 mm, having a plurality of fiber Bragg grating filters and extending in a wall of at least one of said plates in a direction that is not parallel to the axis of casting of the ingot mold.

A continuous casting method includes, conveying a cast slab from a casting mold, stirring a non-solidified portion in the cast slab with a first electromagnetic stirring device, stirring the non-solidified portion with a second electromagnetic stirring device disposed downstream of the first electromagnetic stirring device in a conveyance direction of the cast slab, and subsequently, rolling the cast slab with a reduction roll, in which, the first electromagnetic stirring device alternately imparts the cast slab with electromagnetic force in one direction to cause the non-solidified portion to flow toward one width direction side of the cast slab at a flow rate of at least 5 cm/s, and with electromagnetic force in another direction to cause the non-solidified portion to flow toward another width direction side of the cast slab at a flow rate of at least 5 cm/s.

A continuous casting method of the present invention is a continuous casting method for steel in which a slab at a position where the center solid phase rate of the slab is 0.8 or more and including after complete solidification is reduced by a reduction roll. The roll outer peripheral shape in a cross-section including a roll rotation axis convex shape overhanging outward in a region including a width-direction center position of the slab. The convex shape is a shape that does not have corner portions in a convex shape defining range with a total length of 0.80W on both sides in the roll width direction from the width-direction center position. A reduction roll radius at the width-direction center position is greater by 0.005t or more than a reduction roll radius at both ends of the convex shape defining range.

Feedback is captured and monitored from a radius roll, an upstream rolling unit, and a downstream rolling unit within a casting stand in order to control steel strand casting. The stability of the radius roll is determined, and in response the load share between the downstream unit and the upstream unit is adjusted. When the stability of the radius roll has not changed for a period of time, it may indicate that the steel strand is sagging, and in response the load share of the downstream unit versus the upstream unit is increased. Alternatively, when the stability of the radius roll becomes unstable, such as when the speed of the radius roll is changing, decreasing, or is less than a casting speed, the steel strand may be lifting off of the radius roll, and in response the load share of the downstream unit versus the upstream unit is decreased.

Feedback is captured and monitored from a radius roll, an upstream rolling unit, and a downstream rolling unit within a casting stand in order to control steel strand casting. The stability of the radius roll is determined, and in response the load share between the downstream unit and the upstream unit is adjusted. When the stability of the radius roll has not changed for a period of time, it may indicate that the steel strand is sagging, and in response the load share of the downstream unit versus the upstream unit is increased. Alternatively, when the stability of the radius roll becomes unstable, such as when the speed of the radius roll is changing, decreasing, or is less than a casting speed, the steel strand may be lifting off of the radius roll, and in response the load share of the downstream unit versus the upstream unit is decreased.

A method for operating a casting/rolling system and to a corresponding system for casting and rolling an endless strand material. The casting/rolling system comprises a strand casting machine and a rolling train arranged downstream of the strand casting machine. The method has the following step: controlling the drive for the rollers of the first roller frame of the rolling train by means of a drive control in response to a target value specification of the pass sequence model. Furthermore, the drive of the at least one strand guiding roller is controlled by a strand guiding roller drive control in response to a target value specification of the strand casting machine drive model.