SU869880A1 - Method of cooling rolling rolls - Google Patents

Description

(54) COOLING METHOD FOR EXHAUST ROLLS

The invention relates to the field of rolling production, in particular to the regulation of the thermal profile of the rolls during the rolling process, and can be used to cool the rolled products. The known method of feeding the cooler on the surface of the rolling rolls of sheet mills, which means that the cooler is fed onto the surface of the roll by means of flat machines at an acute angle to the axis of the vapka Cl. The disadvantage of this method is the impossibility of controlling the conditions of cooling the shush rolls. There is a method of adjusting the transverse shape of the strip, which includes changing the flow rate of the cooler, supplied to the working or supporting rolls C2l. The disadvantage of the method is the small range of thermoregulation. The aim of the invention is to improve the quality of the car and reduce the consumption of the chiller. The abandoned goal is achieved by the fact that in a known method, which includes supplying a cooler to the roll surface, a cooler is supplied to the roll surface with intermittent jets: with a pulse ratio O, OZ-1, OO. FIG. 1 shows a roll cooling circuit; in fig. 2 is a scheme of the pulsed supply of the cooler (where c is the irrigation density; T, is the time of supply of the cooler; T is the time of stopping the supply of the cooler). A jet of cooler 1, which is out of the dispenser 2, is applied to the surface of the roll 3 and forms the cooling angle of the oul. In the case of a pulsed feed, a chiller is applied to the swath for a period of time T, and in time span 1 there is no cooling (see Fig. 2). The average surface irrigation density of the cooling surface is directly proportional to the pulse duty cycle C V.ii-t, + t. The pulse impulse can vary over a wide range of 0-1. The pulse repetition time is determined from the condition of continuity of the roll cooling process; t is the pulse repetition time; R is the roll radius; V - circumferential speed of the roll. The main heat removal from the roll is dried precisely on that surface area with an angle / coolf on which the cooler directly falls. The value of heat from a roll at a constant cooling angle is determined by the value of the coefficient of convective heat exchange, which, as studies have shown, depends on the density of irrigation. According to the proposed method, the change in the irrigation density is achieved by adjusting the duty ratio of the pulses of the coolant. The proposed range of adjustment of the pulse ratio is determined by the technological requirement. The upper limit is 1.00. At such a pulse duration, cooling provides removal of heat from rolls having a heat load of about 5 x 1 Okal / h, which corresponds to the most loaded cells of the rolling mill. The reduction of the bore hole of the pulses leads to a decrease in heat transfer from the roll and an increase in its temperature. The lower limit will benefit from the condition that the temperature of the roll does not exceed in order to avoid reducing the strength of the metal of the roll and the appearance of large thermal loads. This corresponds, as the calculations showed, to the research of a pulse duty cycle of 0.03. Thus, the optimal range of regulation of the pulse ratio of the supply of the cooler should be considered 0,031, 00. The proposed method for cooling the rolls is as follows. In the process of rolling the jet of cooler pulses are served on the surface of the roll. If it is necessary to change the thermal profile of the roll, change the duty cycle of the feed pulses in the range of 0.03-1.00. An example of tests proposed and known methods on one of the finishing stands of the mill 2OOO Cherepovets metallurgical plant. In the test process, the cooler pressure, duty cycle, pulse, coolant flow rate and temperature in the middle of the roll barrel were measured. The tests were carried out when rolling a strip of 1.5x15OO mm. The rolling speed was 1 m / s. In the known method, a change in the cooler was achieved only by changing the pressure. The pressure ranges during the test were 1-5 bp. In the proposed method, the change in cooling conditions was achieved by adjusting the duty ratio of the supply pulses of the cooler; .. The range of change of the supply pulses during the tests was O ,, QO. The test results are shown in the table.

As follows from the table, the known method provides the temperature control ranges for the roll 6, with the average consumption of the cooler, and the proposed one - with the average consumption of the cooler 115.

Thus, the proposed method of cooling the rolls allows changing the temperature conditions of the work of the rolls over a wide range, which provides stabilization and more efficient control of the thermal profile of the rolls. In addition, there is no need to create a purge cooling system, since the cooler can be supplied under a pressure of 2-3 atm. with significantly reduced consumption. This leads to an improvement in the quality of the rolled stock and an increase in coolant consumption. (The economic benefit of getting rid of is offered by the method on a continuous wideband broadband hot rolling mill of type 20OO due to an increase in output of 1 sheet of leaf and reduction in water consumption of about 250 thousand rubles per year.

The proposed method is simple to implement and does not require complex equipment.

Claims (2)

Invention Formula A method of cooling the mill rolls, which includes supplying a cooler to the surface of a lump jets, characterized in that, in order to improve the quality of the rolled products and reduce the consumption of the chiller, the chiller is fed to the noBepk roll with intermittent jets with a pulse duration of 0.03-1.00. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 471912, cl. B 21 B 27/10, 1971. 2. Authors du USSR certificate № 275961, cl. B 21 B 27 / 1O, 1968.