RU2553733C2 - Cold deformation of continuous metal strip - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to metallurgy. This process comprises sequential drawing of strip at rear and front tension between three idle rolls. Drawing is performed at several bending device with their mid roll having the diameter smaller that that of extreme rolls and cover by strip through the angle smaller than 180 degrees. Deformation is controlled by definite change in tension with the help of pulling device arranged ahead of first bending device inlet, auxiliary pulling devices arranged between bending devices and pulling device downstream of the last bending device outlet. Strip tension is adjusted by variation of relationship between strip speed at bending device outlet and that at its inlet. Said relationship is kept up not higher than maximum tolerable strip stretching factor at every bending device.

EFFECT: increased deformation, decreased specific power consumption.

1 dwg

Description

The invention relates to the processing of metals without removing chips, in particular, to the production of a metal strip by cold deformation.

A known method of cold deformation of a continuous metal strip in the manufacture of welded pipes, comprising pulling the strip with a pulling device between three non-driven rollers of the bending device, in which the middle roller has a diameter less than the diameter of the extreme rollers and together with the strip covering it at an angle of more than 180 °, is pressed by the tension of the strip to the extreme rollers with a gap between them more than two thicknesses of the strip (AS USSR No. 1500405, publ. 08/15/1989).

The disadvantage of this method is the lack of regulation of the magnitude of the deformation of the strip.

A known method of cold deformation of a continuous metal strip in the manufacture of welded pipes, including pulling it with rear and front tension created respectively by tension and pulling devices, between three non-driven rollers of the bending device, in which the middle roller having a diameter smaller than the diameter of the extreme rollers is covered by a strip of the angle is more than 180 ° and is pressed together with it by pulling the strip to the extreme rollers with a gap between them more than two strip thicknesses, and adjusting the amount of deformation TVOC change its tension without exceeding front tension level, which corresponds to a pulling stress in pulling the strip of 0.85 yield strength of its metal (Russian patent for invention №2412016, published 20.02.2011 g.) - prototype.

The prototype provides the ability to control the magnitude of the deformation of the strip, but its disadvantage is the small value of the deformation of the strip and the increased specific energy consumption per unit of its deformation.

The task of the invention is to increase the magnitude of the deformation of the strip and reduce the specific energy consumption per unit of its deformation.

The technical result is achieved due to the fact that the method of cold deformation of a continuous metal strip includes stretching the strip with rear and front tension between three non-driven rollers of the bending device, in which the middle roller having a diameter less than the diameter of the extreme rollers is covered by a strip at an angle of more than 180 ° and is pressed along with it, the tension of the strip to the extreme rollers with a gap between them more than two strip thicknesses, and the regulation of the deformation of the strip by changing its tension without exceeding ednim tension level, corresponding to the pulling tension in the band 0.85 yield strength of its metal. What is new is that the strip is successively stretched between three non-driven rollers of each of at least two similar bending devices, and in each bending device the tension of the strip is controlled in the range close to its maximum permissible level using a tensioner installed in front of the input side of the first bending device , auxiliary pulling devices installed between the bending devices, and a pulling device installed behind the output side of the last bending device construction. The magnitude of the strip tension is regulated in each bending device by changing the ratio of the speed of the strip exiting a particular bending device to the speed of the strip entering this device. The speed of the strip exiting the bending device is controlled using an auxiliary pulling device or pulling device located immediately behind its output side. The speed of the strip included in the bending device is controlled using a tensioning device located directly in front of its input side or an auxiliary pulling device. The magnitude of the ratio of the indicated strip speeds is provided at a level not higher than the maximum permissible coefficient of strip drawing in each individual bending device.

The increase in the deformation of the strip is achieved by sequentially deforming it in several bending devices (instead of one bending device in the prototype) using a tensioner, auxiliary pulling devices and a pulling device that provide adjustment in all bending devices of the strip tension in a range close to the maximum permissible level . Reducing the specific energy consumption per unit of deformation of the strip is achieved by sequential deformation of the strip in several bending devices, allowing approximately 15-20% of the front tension to be used to pull the strip from one bending device, and the remaining approximately 80-85% of it - to pull the strip from other bending devices.

The drawing shows a diagram of an implementation of the proposed method using a tensioner, four bending devices, three auxiliary pulling devices and a pulling device.

The proposed method is as follows.

Using the tensioning device 1, auxiliary pulling devices 2, 3, 4 and the pulling device 5, a continuous metal strip 6 is successively stretched with rear and front tension between the three non-drive rollers of each bending device 7, 8, 9 and 10.

To overcome the deformation resistance of the strip 6 in the bending device 10, a part (about 15-20%) of the traction force of the towing device 5 is spent. The rest (about 80-85%) of this traction force, together with the assisting traction force of the auxiliary pulling devices 2, 3 and 4 overcomes the deformation resistance of the strip 6 in the bending devices 9, 8 and 7 and overcomes the resistance of the tensioner 1. This rest of the traction force is the rear tension of the strip 6 included in the bending device 10.

When the strip is deformed in the other bending devices, the picture is similar.

For example, to overcome the deformation resistance of the strip 6 in the bending device 8, a part (about 15-20%) of the total traction force of the auxiliary pulling devices 3, 4 and the pulling device 5. not spent on its deformation in the bending devices 9 and 10, is spent. The rest (about 80-85%) of this total unspent traction force, together with the auxiliary traction device 2, which helps it, overcomes the deformation resistance of the strip 6 in the bending device 7 and overcomes the resistance of the tensioner 1. This rest part of the unspent traction force is the rear tension of the strip 6 included in the bending device 8.

In each bending device, the magnitude of the deformation of the strip is controlled by changing its tension in the range close to its maximum permissible level, without exceeding the front tension level corresponding to the pulling stress in the stretch strip of 0.85 of the yield strength of its metal.

The tension of the strip is controlled by changing the ratio of the speed of the strip exiting the bending device to the speed of the strip entering this device. The speed of exit of the strip from the bending device is controlled using an auxiliary pulling device or pulling device located immediately behind its output side. The speed of entry of the strip into the bending device is controlled by a tensioning device located directly in front of its input side or an auxiliary pulling device.

The ratio of the speed of exit of the strip from the bending device to the speed of its entry into this device is provided at a level not higher than the maximum allowable coefficient of stretching of the strip in this bending device, which corresponds to the front tension, which creates a pulling stress of 0.85 of the yield strength of its metal in the drawn strip.

The strain value of the continuous source strip is controlled by changing its tension so that after deformation the finished strip has a predetermined thickness regardless of the longitudinal thickness difference of the original strip.

Most preferred is the following embodiment for controlling deformation of the strip.

Using the auxiliary pulling device 2, a constant exit speed of the strip 6 from the bending device 7 is provided, and with the help of the tensioning device 1, the entry speed of the strip 6 into the bending device 7 is controlled depending on the thickness of the initial strip at the entrance to this bending device. This regulation and the choice of the constant speed level of the strip 6 at the exit from the bending device 7 is carried out so that the strip 6 at the exit from it has a constant thickness regardless of the longitudinal thickness difference of the original strip, and the ratio of the speed of the exit of the strip 6 from the bending device 7 to its input speed into this device was not higher than the maximum permissible coefficient of strip stretching in this bending device.

Using auxiliary pulling devices 3 and 4 and pulling device 5, they provide their constant level of exit speed of strip 6 from each bending device, respectively 8, 9 and 10, at which the coefficient of stretching of the strip in each of them does not exceed its maximum permissible value. The indicated levels of speed of the strip 6 should be selected so as to provide a common coefficient of stretching of the strip in the bending devices 7, 8, 9 and 10, sufficient to obtain the required thickness of the finished strip 6.

The maximum permissible coefficient of strip stretching depends mainly on the ratio of the strip thickness to the diameter of the middle roller. The larger the value of this ratio, the greater the maximum allowable stretch coefficient of the strip. That is, the greater the thickness of the strip and the smaller the diameter of the middle roller, the greater the maximum allowable stretch coefficient of the strip. For example, the test showed that when using a middle roller with a diameter of 39 mm in the bending device, the maximum permissible drawing coefficient of a steel strip with a width of 58 mm is grade 10 according to GOST 16523, corresponding to grade DD11 according to the European normal EN 10111, 2.80 thick; 2.15; 1.72; 1.42; 1.19 and 1.03 mm were 1.32, respectively; 1.27; 1.23; 1.20; 1.18 and 1.16.

The required number of bending devices and auxiliary pulling devices depends on the required overall strip drawing coefficient and on the maximum allowable strip drawing coefficient in each individual bending device.

The proposed method, which provides, in comparison with the prototype, an increase in the total value of the deformation of the strip and a decrease in the specific energy consumption for each percent of its deformation, will make it possible to use it instead of cold rolling a continuous metal strip on a continuous rolling mill. The use of the proposed method instead of cold rolling will reduce several times the capital costs of acquiring equipment and building a plant for strip deformation, reduce tensile wear of the deforming tool, reduce the surface roughness of the strip, increase the accuracy of strip manufacturing in thickness and reduce energy consumption for strip deformation.

Below is the rationale for each of the above advantages of the proposed method of cold deformation of a continuous metal strip in comparison with its cold rolling in a continuous rolling mill.

With the same deformation parameters of the same strip, the metal pressure on the rolls during its cold rolling is approximately 5-8 times higher than the metal pressure on the extreme rollers of the bending device during its cold deformation by the proposed method. Therefore, the mass of equipment of the installation for cold deformation of a continuous metal strip according to the proposed method will be several times less than the mass of equipment of a continuous rolling mill for its cold rolling. Accordingly, the cost of equipment and the cost of building such a facility will be several times lower compared to the cost of equipment and the cost of building a continuous rolling mill.

During cold rolling of a metal strip, its speed in the lagging zone of the deformation zone is less, and in the advance zone of the deformation zone it is greater than the peripheral speed of the rolling rolls. Slippage in the indicated zones of the deformation zone of the strip relative to the rolling rolls and the high specific pressure of the metal on the rolls lead to their intensive wear.

When the strip is deformed according to the proposed method, the rollers of the bending device create two centers of deformation, which are located in zones of changing the direction of the bending of the strip. In these foci, the strip undergoes shear deformation practically without slipping relative to the rollers. The absence of slippage of the strip relative to the rollers and the reduced specific pressure of the metal on the rollers will allow tens of times to reduce the wear of these rollers compared to the wear of the rolls during cold rolling of the strip and to provide a low roughness of the surface of the strip, especially the surface in contact with the middle rollers of the bending devices. The middle rollers have a small diameter and therefore will provide a good study of the surface of the strip.

The methods used in the technique provide high accuracy in controlling the speed of the drives. Therefore, the regulation of the speed of entry of the strip into each bending device and the speed of its exit from this device using the drives of the tensioning device, auxiliary pulling devices and the pulling device will provide high accuracy in controlling the magnitude of the deformation of the strip and, accordingly, will ensure high accuracy of strip manufacturing in thickness.

It is known that with the same strain parameters of the same strip by different methods, the minimum energy consumption occurs when applying the shear strain method, which is used in the proposed method. In addition, in the proposed method of deformation of the strip there is no slippage of the deformable metal relative to the rollers, which does not require energy to overcome the friction forces that occur in the case of such slippage, as, for example, when rolling the strip.

The calculations performed using the test results of the proposed method for the deformation of a steel strip showed that this method, in comparison with cold rolling of a strip, will reduce the energy consumption for deformation of a steel strip by about 10-30%. Moreover, the magnitude of the reduction in energy consumption is greater, the smaller the diameter of the used middle rollers of the bending devices.

Claims (1)

A method of cold deformation of a continuous metal strip, including stretching the strip with rear and front tension between three non-driven rollers of the bending device, in which the middle roller having a diameter less than the diameter of the extreme rollers is covered by a strip at an angle of more than 180 ° and is pressed together with it to stretch the strip to the extreme rollers with a gap between them more than two strip thicknesses, and regulation of the deformation of the strip by changing its tension without exceeding the front tension level corresponding to the pulling a tension in the strip equal to 0.85 of the yield strength of its metal, characterized in that the strip is successively stretched between three non-driven rollers of at least two bending devices, the tension of the strip in each of which is regulated in a range close to the maximum permissible level, by a tensioning device installed in front of the input side of the first bending device, auxiliary pulling devices installed between the bending devices, and a pulling device installed behind the output side the last bending device, and the amount of strip tension is regulated in each bending device by changing the ratio of the speed of the strip exiting the bending device and provided by the auxiliary pulling device or pulling device located behind its output side to the speed of the strip entering this bending device and provided its input side by a tensioning device or auxiliary pulling device, while providing the ratio of these speeds, the value of It does not exceed the maximum permissible coefficient of strip drawing in each bending device.