SU1507465A1 - Method of cold rolling with strip surface cleaning - Google Patents

Abstract

The invention relates to rolling production and can be used in the production of sheet metal. The aim of the invention is to improve the quality of the surface of the strip. The cleaning of the surface of the strip during cold rolling is performed by applying to both sides of the strip before entering the deformation zone of the washing solution with a given temperature, pressure, as well as simultaneous impact on the strip by driven rotating brushes. The new method is to set the mode of supplying the pressure of the washing solution and the peripheral speed of rotation of the brushes according to the experimental dependence, functionally related to the roughness of the surface of the strip. This allows you to adjust the fluid flow depending on the roughness of the strip, helps to establish the optimum ratio between the pressure of the solution and the speed of rotation of the brushes, while ensuring the guaranteed quality of the surface of the strip. 2 ill., 1 tab.

Description

one

(21) 4349377 / 23-02

(22) 12/24/87

(46) 09/15/89. Bksh. № 34 (75) V.N. Skorokhodov, A.I. Ermakov, Yu.I. Usenko, A.I. Traino, V.V. Polk, A.V. Vasiliev, S.G. Gorbunkov, E.A. Bender, L.G. Matyukha and B.C. Yusupov

(53) 621.771.2.09 (088.8)

(56) Japanese Application No. 55-19682,

cl. B 21 B 1/28, B 21 B 45/02, 1980.

For France of France No. 2492282, cl. B 21 B 1/28, R 21 B 45/02, 1983.

(54) COOL ROLLING METHOD WITH CLEANING SURFACE STRIPS

(57) The invention relates to rolling production and can be used to obtain sheet metal. The aim of the invention is to improve the quality of the surface of the strip. Cleaning the surface of the strip during cold rolling is performed by applying to both sides of the strip before entering the deformation zone of the washing solution with a given temperature, pressure, and also simultaneous impact on the strip by driven rotating brushes. The new method is to set the mode of supplying the pressure of the washing solution and the peripheral speed of rotation of the brushes according to the experimental dependence, functionally related to the roughness of the surface of the strip. This allows you to adjust the fluid flow depending on the roughness of the strip, helps to establish the optimum ratio between the pressure of the solution and the speed of rotation of the brushes, while ensuring the guaranteed quality of the surface of the strip. 2 ill., 1 tab.

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The invention relates to rolling production and can be used in the production of sheet metal.

The aim of the invention is to improve the quality of the strip surface by controlling the speed of rotation of the brushes and the pressure of the cleaning solution supplied to the strip.

FIG. Figure 1 shows the dependence of the surface contamination of the strip on the speed of rotation of the brushes and the pressure of the washing solution; in fig. 2 - the dependence of the coefficient K on the roughness of the strip surface is functional.

It is known that during cold rolling on continuous multicell or

single-celled mills in the last stand or passage, especially when training cold-rolled stripes, in the deformation stage with lubricant residues on the surface of the strips get mechanical particles that damage it, leaving defects like accumulation on it, putting it on, rolled in, etc. Moreover, the higher the surface roughness of the strip, the more large mechanical particles are retained on it.

Therefore, in order to remove mechanical particles from the surface of strips having a greater roughness, it is necessary to increase the speed of rotation of the brushes and

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Daapeyis washing solution. Rotating oieTKH provide separation of particles from the surface with overcoming the adhesion forces of particles from the surface of the strip. However, the speed of rotation of the brushes to a greater extent determines the efficiency of separation of particles from the surface and to a lesser extent their removal beyond the limits of the surface of the strip. Therefore, it is obvious that the increase in speed should be steeper to ensure the effectiveness of cleaning the surface of the strip. Consequently, the decrease in contamination is not proportional to the speed of rotation of the brushes, in proportion to, for example, the value of 4v.

The pressure of the cleaning solution to a greater extent determines the efficiency of particle removal beyond the surface of the strip and, to a lesser extent, the separation of particles from the popos. Smaller particles are more easily removed by rotating brushes than by a pressurized solution.

On the other hand, when the pressure of the washing solution is increased, the mechanical particles are removed from the surface of the Strip. Consequently, to maintain the surface of the strip, it is necessary to maintain a certain ratio between the rotation speeds of the brushes and the pressure of the cleaning solution. For example: P- | v To determine the optimal values of the expression P-Jv. which ensure the best quality of the precision strip, are determined by the following conditions. Since the best indicator of the quality of a cold rolled strip is the value of residual pollution, it was chosen as the main condition: the residual pollution of the strip should not exceed 100 mg / m. It is also necessary to take into account that the initial band has a different roughness R, varying from 0.5 to 4 µm. The functional dependences of the residual pollution on the purification conditions were established experimentally, the KPs were set by the mPV index (figure 1). Functions are defined for different strip roughness. So for the band, with Rq 1 µm residual contamination

lanes equal to 100 mg / mm assuming 6.9. In order to determine the functional dependence on the value of R, the parameter K was entered. This parameter is a function of the magnitude

about 5

0 5

0 5 0 5 Q

five

The roughness of the surface of the strip (Fig. 2). Thus, by setting the condition P-JV to 6.9 K, it is always possible to determine the values of P and V, which provide a preventive strip with a residual contamination of no more than 100 mg / m. As a result, not only is the creation of optimal conditions for choosing the speed of rotation of the brushes, the pressure of the cleaning solution, but also the minimum consumption of the cleaning solution is ensured, while the quality level of the strip is always required.

Example. The cold-rolled annealed strip, 0.5 x 1150 mm in size made of steel 08U, rolled up is installed on an uncoiler of a training mill 1700. The strip is rolled on a training mill with a relative reduction of 3-5%. Before entering the cage, the strip passes through a brushing machine, which is equipped with two rotating brushes and nozzles to supply a cleaning solution of (aqueous) soda ash. Studies show that the quality of cleaning the strip, determined by the minimum amount of residual contamination, is proportional to the square root of the linear speed of the brushes and the pressure of the cleaning solution. The water-based cleaning solution has the following composition, g / l:

Trisodium Phosphate6

Caustic soda 7

Surfactant OP-70,9

PMS-200 antifoam 0.08 The temperature of the washing solution is 93 ° C. However, the magnitude of the residual contamination in addition to the above cleaning parameters significantly depends on the state of the surface of the strip, on its roughness.

For example, for a strip with a surface roughness Kd of 1 micron, when the washing solution is supplied to a nozzle with a pressure of P 4 kg / cm and a peripheral speed of rotation of the brushes V 3 m / s, the residual contamination of the strip after cleaning was 100 mg / m, for a strip with Unit 2.0 µm contamination - 110 mg / m; for the band with Rg 4.0 µm, contamination - 156 kg / m (see table).

Thus, the residual contamination of the strip after the washing device increases significantly with increasing roughness of its surface, which leads to the need to introduce a correction factor (Ra) in the formula to determine the maximum allowable contamination of the strip (Fig. 2).

Numerous experiments show that the definitions of P and V of the washing device in order to ensure that the strip is cleaned to a state in which the contamination N exceeds 100 mg / m, it is necessary to use the inequality

 , 6.9 K,

where K is a correction factor depending on the roughness of the strip surface and varying from 0.98 at RQ 0.5 µm to 1.97 if Ra A µm.

The test results presented in table. 1 and 2 show the validity of this formula, the dependence of the parameters P and V of the washing device on the roughness of the strip,

It can be seen from the table and graph that the band pollution decreases with increasing pressure of the washing solution and the speed of rotation of the brushes (P, as well as reducing the roughness of the strip surface, from the same graph you can determine the minimum residual pollution with P and V values given surface roughness of the band. In the case of specifying the values of P and V outside the claims, or the residual soil increases.

g

0 5

0

five

0

or there is an overrun of detergents and unnecessary wear on the brushes of the cleaning device.

Thus, the proposed device allows to improve the quality of the strip surface by adjusting the speed of rotation of the brushes and the pressure of the cleaning solution depending on the roughness of the strip.

Claims (1)

Invention Formula The method of cold rolling with cleaning the surface of the strips, which includes feeding the front and back sides of the strip before entering the deformation zone of the washing solution with a given temperature and pressure, processing the strip with rotating 1-minute brushes, characterized in that, in order to improve the quality of the strip surface, the speed of rotation of the brushes and the pressure of the cleaning solution is set depending on the roughness of the surface of the strip by the thickening P 6.9 K, where P is the pressure of the washing solution, kg / cm; V - circumferential speed brushes, m / s; K 0.98-1.97 — coefficient depending on the roughness of the surface to be treated, K 0.98 — for bands with a roughness of RO of 0.5 μm, K 1.97 - at RQ of 4 μm. 1507465 / la - ffa g 2.0 15 I  W II ,, Continuation table  Kg-Id