[0001] This invention relates to a method of rolling a length of metal bar or wire, especially
hot-rolled bar or wire, and is particularly concerned with the steps necessary to
keep such a metal length stretched at the end of rolling when it passes through a
cooling device after the final roll stand. The invention also relates to apparatus
for carrying out the method. For ease of description, the metal length will generally
be called a bar in the following description, but is not limited thereto.
[0002] It is known to keep a "continuous" metal bar or wire, which is passing through a
finishing roll stand and subsequently through a cooling device, stretched by means
of a set of bridle rolls (also known as pinch rolls) located after the cooling device,
between which the bar is frictionally gripped. Typically the bridle rolls are driven
by independent identical motors with a rated peripheral velocity exceeding the finishing
rolling speed of the bar. See Dutch patent 154129, which discloses use of an adjustable
parallelogram-shaped yoke in a plane at right angles to the passage of the bar, the
yoke being supported by two fixed pivots above and below the rolls. The rolls turn
in bearings in the upstanding sides of the parallelogram-shaped yoke. The motors are
fitted in the said upstanding sides.
[0003] In practice, it has been found that, possibly owing to the large inertial mass involved,
the first part of the bar becomes twisted or buckled in the cooling device. This is
apparently caused by some difficulty of entry of the leading end of the bar into the
bridle rolls, or some slippage in the grip of the bridle rolls, and occurs notwithstanding
the slightly higher speed of the bridle rolls at entry of the bar. This higher speed
arises from the power input to the motors of the rolls which is selected so that the
rolls exert a drawing on the bar to keep it under tension. Bar ends damaged in this
way have to be scrapped, which is costly.
[0004] The object of the present invention is to avoid this disadvantage.
[0005] According to the invention, the power input to the bridle rolls is temporarily increased,
so that, immediately before entry of the bar into the bridle rolls, their peripheral
speed is greater than the peripheral speed corresponding to the normal power input
used during passage of the bar. For instance the power input is briefly increased
as the leading end of the bar approaches, so that the bridle rolls are rotating at
the higher speed at the moment of entry. Thereafter, or even before the moment of
entry, the power input is reduced to the level used while the bar is passing. It appears
that the extra peripheral speed of the bridle rolls causes a considerably greater
tensile force on the bar as the bar begins to pass through them, and this greater
force virtually eliminates twisting or buckling of the head of the bar.
[0006] Preferably the bridle rolls are driven independently by permanently fitted motors
by means of Cardan shafts, but a single drive to the two rolls is possible.
[0007] In order to obtain a good grip on the bar material, the gap between the bridle rolls
before entry of the bar should preferably be about 2 mm smaller than the thickness
of the bar concerned.
[0008] Since a certain amount of time is required to increase the speed of the bridle to
the higher level, it is preferred that the approach of the leading end of the hot-rolled
bar towards the finishing roll stand is observed optically, to provide an electric
signal which is used to cause the temporary increase in power input.
[0009] An embodiment of the invention will now be described by way of example and with reference
to the accompanying drawing.
[0010] In the drawing,
Fig. 1 is a diagrammatic side view of a finishing roll stand, cooling device, bridle
rolls, shear and run-out table, to which the method according to the invention is
applied;
Fig. 2 is a double graph to clarify the operation of the method.
In Fig. 1 is shown part of a mill train for the hot-rolling of bar and wire material
WS. The finishing roll stand W is followed by a cooling device K, and by a pair of
bridle rolls Rl and R2, between which the "continuous" bar is frictionally gripped,
relatively lightly. S indicates a shear and U the run-out table or cooling bank for
the material which is cut to measure by the shear.
[0011] The bridle rolls Rl and R2 are driven independently through Cardan shafts CD1 and
CD2 by permanently fitted electric motors Ml and M2, which are supplied from a static
frequency convertor ST. In one practical embodiment, the motors Ml and M2 are squirrel-cage
rotor motors rated at 3.75 kVA each and the static frequency convertor has an output
of 15 kVA with a yield of 90%. The convertor ST receives signals from a photo electric
cell F which detects the presence of the hot bar material in the mill train before
the finishing stand W, the cell being located above the mill train before the stand
W. The convertor also receives signals from a tachogenerator TG which determines the
finishing rolling speed, being linked to the finishing stand W. Data are also entered,
indicated by R in Fig. 1 relating to the diameter correlation and the drawing adjustment
for the bar being rolled.
[0012] Fig. 1 shows, highly diagrammatically, that the upper bridle roll Rl is fixed while
the bottom bridle roll R2 is movable since the frame in which the roll R2 is fitted
can swing round a pivot located "upstream" with respect to the bar travel. An adjustable
stop A determines the minimum gap between the two rolls Rl and R2. This gap is set
at about 2 mm less than the thickness or diameter of the bar to be drawn. An air cylinder
C, supplied from a compressed air network through a reducing valve V, normally presses
the frame in which the roll R2 is fitted against the stop A (whose position is adjustable
by means of a screw spindle). As soon as the bar arrives between the rolls Rl and
R2, the frame leaves the stop and the air cylinder C ensures that the bar is spring
gripped between the two rolls.
[0013] The gripping surface of the two rolls is profiled, e.g. by applying a pattern of
recesses or holes and then hardened. When changing the rolls, e.g. because of wear
or to change to another diameter of roll, the top roll Rl can be placed in the correct
position in the rolling line by adjusting the frame carrying it.
[0014] Fig. 2 shows how a temporary accumulation of energy can be used to keep the bar stretched
when entering the bridle rolls. Time is indicated along the horizontal axis. In the
upper graph, the rotational speed n(rpm) of the bridle rolls is given on the vertical
axis, and in the lower graph the control signal to the bridle roll motors is shown
on the vertical axis. This control signal indicates the period of time for which a
higher power input is applied. Power input can be accurately controlled by means of
the static frequency convertor ST, using frequency control of the motors.
[0015] Fig. 2 thus shows that there is a temporary increase in the power input over a time
period t
s which leads (see the upper graph) to an acceleration of the bridle rolls to a higher
speed, this acceleration occurring over a time period of t. The initial speed of the
bridle rolls (given as 800 rpm in this example) is the idling speed of the rolls at
the normal power input which is used when the bar is actually passing; this idling
speed is 5 to 10% higher than the actual rolling speed of the bar. When the bar is
passing, the bridle rolls must of course run at a peripheral speed equal to the rolling
speed of the final roll stand W, as indicated by the slightly lower speed (e.g. 760
rpm) at the right hand side of Fig. 2.
[0016] As mentioned above, when the approach of the leading end of the bar is signalled,
the power input to the bridle roll motors is increased, leading to a rise in speed
of about 25% in this case (to about 1000 rpm). This rise is synchronised so that the
leading end of the bar arrives after the higher speed is reached. In this case, the
moment of arrival of the bar corresponds with the end of the time period t and is
followed by the decline in speed to the level corresponding to the final rolling speed.
It is this initial tension applied to the bar which minimises the damage to the head
of the bar. This leads to a considerable reduction in wastage of material.
[0017] A 25% increase in speed is indicated above (to 1000 from 800). Suitably, this increase
is in the range 15% to 35%.
[0018] The time t
s during which the control signal is present is not fixed, nor is the time t
v over which the rotating parts are speeded up. Both depend on, inter alia the speed
of the bar material. The time t
s is adjusted in dependence on the roll speed (via TG) automatically in ST.
[0019] There is a linear correlation between the supply frequency and the rotational speed
n of the squirrel-cage rotor motor under zero load. As the frequency is briefly increased,
the speed of the drive motors Ml and M2 rises from, in this example, 800 to 1000 rpm.
As a result, more rotational energy is accumulated in the rotating parts, i.e. the
rotors of the motors Ml and M2, the Cardan shafts CD1 and CD2 and the rolls Rl and
R2.
[0020] If the photo-electric cell F is located at a distance of about 7 metres from the
bridle rolls Rl, R2, and the speed of the bar is about 14 metres per second, 0.5 seconds
is available to increase the speed. On entering the rolls Rl,R2, the head of the bar
will be subjected to a considerable tensile force between the rolls owing to the difference
in the speed between these rolls and the stand W, so that the head of the bar will
remain straight.
[0021] Because also the gap between the rolls at the time of entry of the bar is about 2
mm less than the diameter of the bar, there is less slip on entry between the bridle
rolls and the bar material, so that there is an additional advantage that the bridle
rolls last longer.
1. Method of rolling a length of metal bar or wire wherein the metal length (WS) is
passed through a roll stand (W) and subsequently through at least one cooling device
(K) and is maintained under tension in the cooling device (K) by means of an opposed
pair of driven bridle rolls (Rl,R2), located after the cooling device, which frictionally
grip the metal length between them and which are driven, during passage of the metal
length, with a power input which, if the metal length were absent would cause the
bridle rolls to rotate at a first peripheral speed of the bridle rolls higher than
the rolling speed of the metal length in the said roll stand (W), characterized in
that:
at the moment when the leading end of the metal length reaches the bridle rolls, the
bridle rolls are rotating at a second peripheral speed higher than said first peripheral
speed.
2. A method according to claim 1 wherein the bridle rolls are normally run, during
passagebf a metal length and in the intervals between the passage of metal lengths,
at the said power input corresponding to the said first peripheral speed, and upon
approach of the leading end of a metal length the power input is transitorily increased
in order to cause the bridle roll speed to rise to said second peripheral speed.
3. A method according to claim 1 or claim 2 wherein the two bridle rolls (Rl,R2) are
driven separately by respective electric motors, via Cardan shafts.
4. A method according to any one of claims 1 to 3 wherein before insertion of the
metal length between the bridle rolls, there is a gap between the bridle rolls with
a width of about 2 mm less than the thickness of the metal length.
5. A method according to any one of the preceding claims wherein the approach of the
leading end of the metal length to the bridle rolls is detected by optical means (F)
before the said roll stand (W), the output signal of the optical means being used
to actuate a rise in the speed of the bridle rolls to said second peripheral speed.
6. Apparatus for carrying out the method of claim 4 having a roll stand (W), a cooling
device (K), bridle rolls (Rl,R2), drive motors (Ml,M2) for the bridle rolls (Rl,R2)
in the form of squirrel-cage rotor motors supplied by a static frequency convertor
(ST), a photo-electric cell (F) arranged to detect the presence of a hot metal length
(WS) in front of the roll stand (W), and a tachogenerator (TG) linked to the roll
stand (W) to determine the rolling speed therein of the metal length, the output signals
from the cell (F) and tachogenerator (TG) being fed to the frequency convertor (ST)
for control of the motors (Ml,M2) in dependence on those signals.