Advancement of Roll-Gap Control to Curb the Camber in Heavy-Plate Rolling Mills

Andrey A Radionov,Boris M Loginov,Vadim R Gasiyarov,Vadim R Khramshin,Alexander S Karandaev

doi:10.3390/app11198865

Andrey A Radionov, Boris M Loginov + Show 3 more

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https://doi.org/10.3390/app11198865

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Abstract

The quality of steelwork products depends on the geometric precision of flat products. Heavy-plate rolling mills produce plates for large-diameter pipes and for use in shipbuilding, mechanical engineering, and construction. This is why the precision requirements are so stringent. Today’s Mills 5000 produce flat products of up to 5 m in width; the operation of these units shows ‘camber’ defects and axial shift of the roll at the stand exit point. This induces greater loss of metal due to edge trimming and involves a higher risk of accidents. These defects mainly occur due to the asymmetry in the roll gap, which is in turn caused by their misalignment in rolling. As a result, the feed varies in gauge, and the strip moves unevenly. The paper’s key contribution consists in theoretical and experimental substantiation and development of a set of control methods intended to address roll-gap asymmetry. The methods effectively compensate for the asymmetry resulting from the “inherited” wedge, which preexists before the strip enters the stand. They also compensate for the “ongoing” roll misalignment that is caused by the difference in force on the opposite side of the stand during rolling. This comprehensive approach to addressing camber and axial displacement of the feed has not been found in other sources. This paper presents a RAC controller connection diagram that ensures that the roll gap is even across the feed. The paper notes the shortcomings of the design configuration of the controller and shows how it could be improved. The authors have developed a predictive roll-gap asymmetry adjustment method that compensates for the deviations in gauge during the inter-passage pauses. They have also developed a method to control gap misalignment during rolling. The paper showcases the feasibility of a proportional-derivative RAC. The methods have been tested by mathematical modeling and experimentally. The paper further shows oscillograms sampled at Mill 5000 after implementing the developed solutions. Tests confirm far better precision of the screw-down mechanisms on the opposite sides of the stand. This reduces the variation in gauge across the feed and thus curbs the camber defect. As a result, the geometry of the flat improves, and less metal is lost in trimming. The paper further discusses how the RAC controller interacts with the automatic gauge control system. The conclusion is that these systems do not interfere with each other. The developed systems have proceeded to pilot testing.

Highlights

Today, at least 12 plate Mills 5000 are operated worldwide, five of which are in Japan, three in Germany, three in the Russian Federation, and one in Shanghai (BAOSTEEL, China)
The disturbance causes an increase in the force FDS (Panel 2), which triggers a nearly simultaneous increase in the signal of the roll alignment control (RAC) controller, Panel 3
We introduce the notion “differential rolling force”, which is indirectly defined as measured on-line pressure difference in hydraulic cylinders

Summary

Introduction

At least 12 plate Mills 5000 are operated worldwide, five of which are in Japan, three in Germany, three in the Russian Federation, and one in Shanghai (BAOSTEEL, China). They are designed to produce flats of up to 5 m in width and up to 36 m in length. The key quality requirement is the geometric precision of the finished sheet or plate and minimum edge trimming. This is attained by automated electric drives and process parameter control systems. The most commonly occurring feed (intermediate product between plate slab and ready sheet) defect are the bend in the motion plane (defect “camber” Figure 1b) and its lateral shift at the output of the stand [1,2,3]

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