SU1200209A1 - Method of checking tension of steel strip on cold rolling mill - Google Patents

Abstract

A METHOD FOR MONITORING A STEEL STRIP TENSION ON A COLD ROLL KI MILL, consisting in magnetizing a steel strip under tension, so that, in order to improve the control accuracy, an external magnetic field is imposed on the steel strip , not exceeded 5 e, directed normally to its surface, measure the value of induction, proportional to the total value of tensile forces and material anisotropy, affect the external field corresponding to saturation, and measure the amount of induction, proportional ionalnuyu anisotropy.

Description

The invention relates to the field of magnetic measurements and is intended for use in cold rolling mills when controlling the tension of a strip. The aim of the invention is to improve the accuracy of monitoring the tension of the strip by compensating for the influence of the crystallographic texture. Figure 1 presents the device implements the method; figure 2 - dependencies, as shown below. The device (Fig. 1) contains an open lii-shaped magnetic circuit 1 with pole rods 2-4. A magnetizing coil 5 is placed on the middle pole rod 3. A compensation Hall sensor 6 and a Hall sensor sensor 7 are placed and fixed on the jBocax rods 2 and 4. The distance in and 6 between the magnetizing rod 3 and the outer rods 2 and 4 is chosen so as to provide different magnetic field strengths 8 gaps S, and Sji. I Hall compensation sensor 6 has an output divider, the output terminals of which are connected in series with the output terminals of the Hall sensor 7. The device works as follows. After installation of the device by the poles of rods 2-4 on a controlled rolled strip 9 with a certain gap 8, the magnetizing coil 5 is connected to a DC source (not shown), and the series connected terminals of the measuring Hall sensor 7 and the splitter signal of the Hall compensation sensor 6 are connected to the measuring Under the influence of the magnetizing winding 5, a magnetic flux occurs in the rod 3 (which is distributed to the magnetic fluxes P and Pd, the magnitude of which depends on the strength of the magnetic field Weaving B, and 8j. If the controlled material is, for example, tr anformal steel with a silicon content of 3.8Z, then 6 | and B are chosen in such a way that in section 2 and respectively in the gap about the strength of the field weak magnetic field m (about 2 A / m), and in section C, and in the gap o, the field strength corresponds to saturation. Then the magnetic flux Φ depends only on the degree of steel texture, and 9 depends on the degree of texturing , and from mechanical stresses in steel. Under the influence of the magnetic flux P, a signal proportional to the texturing of the stage appears on the output terminals of the Hall sensor 6. Hall 7 - a signal proportional to the voltage and texturing of the steel. The signal from the Hall sensor 6, the passage through the divider, decreases and becomes the same with the signal component of the sensor 7 associated with the steel stating. Due to the counter-on from the output signal of the sensor 7, the output signal from the divider of the sensor 6 is subtracted. The resulting difference signal is proportional only to the mechanical stress and does not depend on the crystallographic texture, which ensures high accuracy of the measurement results. In the field of weak fields (, 2-5), induction 8 for cold-rolled transformer steel EZZO is very sensitive to external tensile stresses (Fig. 2). Thus, at H 1 Oe, induction B at c5 0 is about 4 times higher than at b 10. kg / mm, which indicates a high sensitivity of the magnetic characteristics in the field of weak fields to voltages m. With increasing intensity of the external magnetic field H up to 2.5-30 Oe, all curves are magnetized, corresponding to d 0-10 kg / mm, practically merge into one curve, i.e. magnetic induction does not depend on external tensile stresses. The induction sensitivity to crystallographic texture is high both in the field of weak fields and in the field of strong fields. So, for steels E47 and E370, which significantly differ in the degree of crystallographic anisotropy, the ratio of inductions at E is B E47 / B E370 6.1 / 13.5, B E47 13 17 PR "40" in E370

Thus, by measuring the magnetic induction in the region of weak magnetic fields and at saturation, it is possible to determine the relative change of induction B under the action of stresses applied to the metal.

1200209-4

The use of the proposed method allows an increase in the accuracy of control of the strip tension on rolling mills, which leads to an increase in the reliability of their work, to a decrease in the strip slip.

Claims (1)

METHOD FOR CONTROL OF TENSION OF THE STEEL STRIP ON THE COLD ROLLING STABILITY, which consists in the magnetization of a steel strip, finding the Institute (72) Yu.D.Zheleznov, A.G. Zhuravsky, V.F. Krepakova And S.P. Nikolayev (53) 621.3) 7.44 (088.8) (56) Grigoryan G.G., Zheleznov Yu.D., Cherny V.A. et al. Tuning, stabilization and control of the sheet rolling process. M .; Metallurgy, 1975, p. 315-319. Druzhinin V.V. Magnetic properties of electrical steel. L .: Gosenergoediat, p. 207, 1962. under tension, characterized in that, in order to increase the control accuracy, an external magnetic field not exceeding 5 Oe is applied to the steel strip, directed normally to its surface, an induction value proportional to the total value of the tensile forces and anisotropy of the material is measured, they are exposed to an external field corresponding to saturation, and measure the value of itsduction proportional to anisotropy.