RU2164179C2 - Method for skin pass rolling of rolled thin sheets - Google Patents

Abstract

FIELD: rolled stock production, namely, skin pass rolling of cold rolled sheet iron. SUBSTANCE: method comprises steps of rolling with small reduction values in such a way that at temperature of skin pass rolled metal lower than 45 C, reduction values are equal to 0.5-2.2%, at temperature 45-75 C - to 0.5-1.5% and at temperature 75-90 C - to 0.5-0.8%. EFFECT: enhanced efficiency due to lowered time period for cooling before skin pass rolling and increased temperature of skin rolled metal while keeping all mechanical properties of metal. 1 tbl

Description

 The invention relates to the field of rolling production, namely to the training of cold rolled sheet metal.

The technology for training sheet metal is described in the book by N.I. Scheftel. Cold rolling of sheet steel, s. 103-104, 108-117. The technology of training consists in rolling with small relative reductions at a temperature of rolled metal 30-40 ^o C. The disadvantage of the method of training is the temperature limit of the trained metal (not higher than 40 ^o C), which requires a significant cooling time and leads to a decrease in productivity.

 Closest to the proposed invention is a method of training sheet metal, which consists in the fact that to obtain all the necessary properties when training sheet metal on a two-stand mill, the degree of deformation should be in the range of 1.75-3.0%. The method is described in the book S.P. Antonova, M.I. Kuprina, A.F. Pimenova, L.V. Radyukevich, N.M. Shakirova. Cold rolling of tin. M .: Metallurgy, 1965, p. 198-204.

The disadvantage of this method of training is that with this method it is not always possible to obtain a metal with the desired mechanical properties, for example, if the metal is trained at a temperature above 40 ^o C, i.e. there is also a limitation on the temperature of the trained metal.

 The technical problem solved by the invention is the expansion of the temperature range of the trained metal, which leads to an increase in productivity.

To solve this problem, the method of training sheet metal, including rolling with small reductions, is carried out at a temperature of the trained metal not exceeding 90 ^o C, with relative reductions of 0.5-2.2%, while at a temperature of up to 45 ^o C, the reductions do not exceed 2.2%, at a temperature of 45-75 ^o C compression does not exceed 1.5%, and at a temperature of 75-90 ^o C compression does not exceed 0.8%.

 The method of training is as follows.

Annealed cold-rolled strip with a thickness of 0.20-0.36 mm, wound into a roll, put on a roll conveyor (receiving rack) of the training mill. From the receiving rack, the roll is worn on the unwinder drum. After installation in the uncoiler, the front end of the strip is refilled into the rolls of the tensioner. Before the task of the strip into the rolls, temperature measurements are made with an ETP-M type thermocouple. Accuracy class ± 2.5. After filling the strip into the mill, the tension of the strip between the stands and the coiler is set and the compression mode is selected depending on the measured temperature of the strip. If the temperature of the metal before training to 45 ^o C, then the relative compression set in the range of 0.5-2.2%. For reductions below 0.5%, an undressed metal is used, and for reductions above 2.2%, the necessary mechanical properties (for example, hardness) of the metal are not achieved. If the temperature of the metal before training 45-75 ^o C, then the relative compression set 0.5-1.5%. With reductions of less than 0.5%, the metal is under-trained, and with reductions of more than 1.5%, the required mechanical properties are not achieved. If the temperature of the metal before training 75-90 ^o C, then the compression choose 0.5-0.8%. Here, also, with reductions of less than 0.5%, the metal is under-trained, and with reductions greater than 0.8%, the necessary mechanical properties of the metal are not achieved. The results of the experimental trainings of tin from steel 08PS 0.28 mm thick, carried out by the proposed method and prototype, are shown in the table. The required upper hardness after training in this case should be 58.5 HRT.

From the table it follows that when training tin according to the prototype with increasing temperature of the training metal, the required hardness is not achieved (example No. 2). When training on the proposed method, the hardness does not correspond only in those cases when the relative compression is beyond the scope of the claimed (example N 5,8,11). Thus, the proposed method can carry out the training of tin, significantly raising the temperature limit (up to 90 ^o C), while the mechanical properties correspond to technical requirements. Thus, the production cycle of tin is reduced by reducing the cooling time, which leads to a significant increase in production without additional capital costs.

Claims (1)

The method of training sheet metal, mainly tin, including rolling with small reductions, characterized in that the training is carried out at a temperature of the trained metal, not exceeding 90 ^o C, with relative reductions of 0.5 - 2.2%, while at a temperature of up to 45 ^o C compression does not exceed 2.2%, at a temperature of 45 - 75 ^o C compression does not exceed 1.5%, and at a temperature of 75 - 90 ^o C compression does not exceed 0.8%.

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