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ROLLING
MILL CONFIGURATION - The history of the
rolling process is presented commencing with its early origins and following through to
the modern continuous strip production techniques. Different rolling configurations for
cold and hot rolling mills are also discussed. The basic mill configurations, two and four
high mills, cluster and six high mills are compared. Different mill housing designs are
examined in terms of the relationship between the measured rolling load and the forces
applied to the mill housing. These relationships are fundamental to the measurement and
control of mill forces. Rollstack alignment, coilers and their geometry and
instrumentation technology are other items presented.
AN INTRODUCTION TO THE METALLURGY OF
SHEET PRODUCTS - An holistic knowledge
of rolling theory, mill operating practices and product metallurgy is desirable for
engineers, operations and technical personnel charged with the responsibility of
optimising mill performance and product quality. The final material properties are a
function of pre-rolling processing, the rolling process and post-rolling processing. The
development of material properties through the various manufacturing stages, including
rolling, are considered. The main sheet products are considered: steel, aluminium and
copper/ brass.
HOT TANDEM MILL CONTROL DESIGN
- A review of actuators and mill responses
to various process and actuator disturbances leads to the design of thickness, tension and
temperature controls for tandem hot finish mills. Both mills with interstand loopers and
tensiometer rolls are considered.
INTRODUCTION TO ROLLING CONCEPTS
- This introductory lecture introduces a range
of important physical concepts whose understanding is critical to an appreciation of the
rolling process. The notation, units and symbols employed in the Hatch IAS course and published
information are also described so that all delegates have a common “language” in
which to converse. The various phenomena occurring in the rollgap deformation zone between
the work rolls are explained in detail and include: yield stress behaviour of plastic
deformation of common materials, physical properties, frictional effects, surface
interactions between the strip and the work roll, definition of forward slip. Finally a
summary of the characteristic differences between the different types rolling is
presented, covering hot, cold, tinplate, temper and foil mills.
ROLLING THEORY - The equations describing the two dimensional deformation of
the metal in the rollgap and their use in predicting force, torque and slip are presented.
This lecture focuses on the circular arc models, providing a brief derivation the model
developed by Orowan in 1943. This model employs the iterative solution of the roll
deformation as described by the Hitchcock (1935). The contributions of the elastic
compression and recovery regions and inhomogeneous deformation in rollgap modelling are
included. The lecture also presents a simplified graphical model which highlights the
effect of changes in tension, yield stress, friction and strip thickness on the roll force
and slip. Typical pressure distributions for difference rolling scenarios and expected
model accuracy conclude the presentation.
ROLLGAP SENSITIVITY COEFFICIENTS
- Rollgap sensitivity analysis allows the use of
a linear model to represent a non-linear rolling process. A rollgap sensitivity is a
single number representing the change in one rolling condition with respect to another. A
computer model can generate a sensitivity coefficient, which will be applicable for the
simulated rolling condition. The sensitivity can be used to estimate for example the
change in roll force cause by a change in entry thickness or the change in entry thickness
required to achieve a specified roll force change. Alternatively a sensitivity coefficient
could be measured on a rolling mill and used for future reference on a particular product.
MODELLING OF THIN STRIP, FOIL AND
TEMPER ROLLING - This lecture extends
on the material covered in the rolling theory lecture, examining those circumstances where
the circular arc model fails to adequately predict the strip deformation. Alternative
models are examined and the non-circular arc model proposed by Fleck et al. is presented.
A comparison of the circular arc and non-circular arc models highlights their differences.
A number of particular rolling scenarios including skin pass rolling, asymmetric rolling
foil and temper rolling are covered. The impact of lubrication and friction on foil
rolling and surface roughness in temper rolling are studied. The lecture concludes with a
brief coverage of roll touching or kissing.
ROLLGAP MODELLING FOR HOT ROLLING
- The trends towards tighter
tolerances for width, thickness and finish temperature of hot rolled strip, and towards
thinner finish thicknesses, have driven the development of more accurate rollgap models
for online use. These new models are replacing older, less sophisticated models which were
generally tabular in form, schedule specific and heavily dependent on adaption for
effective performance. The influence of temperature, recrystallisation, precipitation and
phase transformations complicate the modelling effort. The key issues to be addressed are
considered and developments in the modelling of hot yield stress, friction, slip and strip
temperature are reviewed. An indication of the expected performance that can be achieved
in the strip quality parameters with these new models is provided.
MILL THERMAL ANALYSIS - The thermal flows within the mill impact upon shape and
profile via the thermal expansion of the roll, on the strip properties via the strip
temperature change, the lubricant via the heat generated during rolling and thermal
fatigue of the rolls. Mill thermal analysis examines the rollgap heat flows which allows
the derivation of strip temperature models for the rollgap and between the stands.
Particular attention is given to the interstand behaviour of hot steel and aluminium and
runout table strip cooling. This often requires the two dimensional analysis of the
temperature distribution in hot rolling mills.
ROLL THERMAL CAMBER ANALYSIS
- The development of the roll thermal expansion
or camber is studied. Experimental measurements on roll temperature are used to study the
internal heat flows which occur in the roll. The solution of the roll temperature field
and subsequent thermal expansion are described for the case of continuous steady state
rolling. Simple algorithms to predict the thermal camber behaviour are described. The
lecture moves on to show how the development of thermal camber over time for both
continuous and batch rolling can be predicted. The response of thermal camber to a single
spray, a situation which occurs in shape spray control systems is highlighted. The lecture
finishes with practical issues in the measurement of parameters required for the
prediction of thermal camber.
INTRODUCTION TO STRIP PROFILE,
SHAPE AND FLATNESS CONCEPTS - This
lecture gives an introduction to definitions and causes of thickness profile, strip shape
and flatness of strip. A parametric representation of measured flatness and thickness
profile is described. The origins of thickness profile and shape in both the hot mill and
cold mill regimes are discussed. Apart from the typical rollgap interaction affecting
these defects, other causes and effects due to friction, lubrication, sprays, product
qualities, mill alignment and temperature are important. Causes of flatness defects that
may not necessarily be manifest in a shapemeter display but affect final product quality
can be critical and difficult to diagnose. Shape parameter sensitivities to roll force,
roll bending and thermal camber are important for calculating controller gains for shape
control systems.
SCHEDULING OF HOT REVERSING MILLS
- While modelling of rolling is well covered in
the literature there is little published about the strategies behind the calculation of
pass thicknesses and drafts to satisfy mill equipment constraints and strip flatness and
profile requirements, or the calculation of pass speeds and spray patterns to achieve the
required strip surface quality and last pass exit temperature. Several drafting strategies
are compared, and the normalised drafting strategy is considered in some detail, as it is
a robust, versatile and practical method for online use. A limited discussion of width
drafting strategy is provided. Some results from an online scheduling algorithm based on a
normalised drafting strategy are presented.
TANDEM COLD MILL SETUP STRATEGIES
- The objective of the mill setup strategy is to
provide a consistent and reliable prediction of threading references which, in conjunction
with the experience and skill of the roller, will achieve the most efficient rolling
operation. Constraints for the scheduling algorithms are defined. There are two major
components - the strategies for scheduling tensions, thickness reductions and last stand
roll force and the calculation of actuator references based on models and physics. In
particular, a tension strategy based on mill exit thickness, a reduction strategy based on
a normalised reduction technique and last stand roll force based on specific force is
described. A calculation of control actuator references for threading of tandem cold mills
to minimise off-thickness material and threading delays can significantly effect the
efficiency of operation. Schedule dependent controller gains are calculated to improve
thickness and tension control.
HOT FINISHING MILL SETUP
STRATEGIES - While modelling of rolling
is well covered in the literature there is little published about the strategies behind
the calculation of stand thicknesses and reductions, interstand tensions or the
calculation of mill exit speed to satisfy strip temperature requirements. Different
thickness reduction algorithms are compared and an algorithm for interstand tensions is
provided. The influence of temperature on the setup model calculations for a hot finishing
mill is considered. A number of algorithms for calculating the runout table spray quantity
for steel rolling are presented.
ACTUATORS, INSTRUMENTATION & MILL PERFORMANCE - The operation and performance of a rolling mill is
influenced by many factors, a key one being the design, speed, accuracy and robustness of
the actuators. An introduction to AC and DC drive motors, hydraulic and electric screw
rollgap position actuators, roll bending actuators and electric, hydraulic and pneumatic
interstand loopers in hot finishing mills are presented. The merits of each type of
actuator are discussed, with typical response times and design limitations.
A MODEL FOR FLATNESS AND PROFILE
ANALYSIS - The modelling of strip
flatness and profile is described in terms of its component models. These include the
three dimensional deformation in the rollgap, the rollgap entry and exit tension stress
analysis, the roll stack deflection and the interstand creep. One important aspect of
shape and profile development is the tension stress feedback mechanism which occurs in the
rollgap. This feedback loop is a predominant mechanism in the development and control of
shape and profile. After development of the model a number of model applications are
studied including the control of profile and shape in hot and cold rolling tandem mills
and the impact of spread and thermal camber on shape and profile.
STRIP WIDTH CONTROL - A conceptual design of width control systems, typically
employed at the roughing and finishing stands of steel hot strip mills, is described. The
lecture focuses on the many physical phenomena present in rolling which modify the final
strip width. These include: spread in flat rolling, edging pass efficiencies, slab end
effects in reversing mills, width changes due to interstand creep and bending stresses and
thermal expansion behaviour. Typical practices and the control of slab end effects by
dynamic edger position control is addressed.
FUNDAMENTALS OF THICKNESS
CONTROL - The principle concepts
and design issues of the various thickness controllers employed on single stand mills are
presented, through the development of process and control models. The strengths and
weaknesses of each controller are compared. Model based time delay compensation for faster
tuning of conventional feedback controllers with feedback path time delay is explained.
Peripheral issues such as mill stretch, speed effects and tension interactions are
discussed also. This lecture is an excellent introduction for the more challenging issue
of designing thickness and tension controls for tandem mills. The thickness controllers
described are also used on tandem cold mills and hot mills.
DESIGN OF INTEGRATED CONTROL SYSTEMS FOR
TANDEM MILLS - Many of the concepts and
issues in the design of thickness and tension controls for tandem mills are not intuitive.
Unlike in single stand mills, there is scope for loop coupling and interaction. The design
of an integrated, non-interacting tension and thickness control scheme is presented for
both cold mills and hot mills. The controller design is developed from a consideration of
the uncontrolled tandem mill response to a range of disturbance types, and the response to
the use of different rollgap and motor actuators for control action. Other issues examined
are the use of schedule dependent controller gains and the potential interaction of
multiple thickness controllers.
SHAPE CONTROL SYSTEMS - The online measurement of strip shape which began in the
early 1960's has seen extensive development in the area of shape control as shape has
become one on the important strip quality parameters. The design of shape control systems
commences with an examination of the major shape disturbances and the different types of
actuators available. Roll bending, roll crossing, roll side shifting, hydraulically
modified rolls, segmented rolls and cold and hot sprays are all used for shape control.
The sensitivity of strip shape to these actuators and the common forms of disturbance form
the fundamental basis for the design of the shape control system. Other important aspects
covered include shape measurement and signal processing. An examination of the performance
of different levels of automation concludes this lecture.
PROFILE CONTROL STRATEGIES
- The lecture starts with a discussion of the
physical phenomena which affect the thickness profile. The mathematical representation of
typical thickness profiles is discussed and common methods of measurement described. The
design of automation systems for profile control is reviewed and the characteristics of
currently available measurement and actuator systems described. The mathematical
formulation of a vector based profile setup model algorithm is developed which has many
important advantages over the systems installed at most mills. Typical performance of
online thickness profile models and control systems is given as well as a discussion of
practical constraints and future directions for further improvements.
ADAPTION OF ROLLING MILL MODELS
- There are a number of model coefficients that
vary over time as mill conditions change or are not accurately known for every product. If
these are not addressed adequately, the model errors lead to operating difficulties. The
concept of adaption, or model learning is discussed using simple algorithms for achieving
enhanced on-line model performance. A number of more recent techniques, such as Kalman
Filtering and Neural Networks are introduced. Many practical aspects of model adaption
schemes for reversing and tandem mills and methods of tuning adaption filters for optimum
performance are presented. Ensuring that the number of adaption parameters is minimised
and the parameters are not interdependent is of prime importance.
MILL VIBRATION PHENOMENA
- Mill vibration has become an increasingly
important operational issue in both cold and hot rolling mills as mill size and speed have
increased. Torsional, third octave and fifth octave chatter, common vibration modes which
occur in cold and hot mills, are studied. For each of the three modes of vibration the
underlying mechanisms involved are discussed. For third octave chatter a stability
criteria for the critical rolling speed is presented. This allows the effect of the major
parameters on the critical speed to be determined. Methods of suppressing third octave
chatter are examined including the design, development and testing of the vibration
inhibiting piston. The current understanding of the mechanism and methods for suppression
of fifth octave chatter are then presented.
LUBRICATION & COOLING
- Lubrication and cooling remains a highly
specialised field in the rolling industry. This lecture provides an overview of the major
principles of lubrication and cooling, their impact upon the automation of rolling mills
and some of the practical aspects of this subject. It commences examining factors which
impact upon the selection of the lubricant and describes the different modes of
lubrication. Differences between water based emulsions, dispersions, stabilised
dispersions and petroleum based solutions are highlighted. It also examines the design of
roll coolant application and solution systems.
CASE STUDY IN REVERSING COLD MILL
AUTOMATION - This lecture discusses the
issues involved in automating single stand rolling mills, highlighting the areas of
similarity and difference with tandem cold mills. The strategy for selecting suitable
tensions and reductions is described. A discussion is included on the importance of
selecting the correct winding tensions to avoid coil collapse and inter-wrap sticking
during batch annealing in downstream processing. The components of a state-of-the-art
dynamic thickness and flatness control are summarised. A discussion on the relative merits
of different types of measurement transducers is included. Finally, notes on the design of
performance reporting and fault diagnosis systems are provided.
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