FIELD OF THE INVENTION
[0001] The invention relates to methods and apparatus for producing bundles of steel bars
which are cut to length and particularly in a continuous operation.
[0002] More particularly, the invention relates to producing such bundles which are customer-ordered
and are of specific length.
[0003] Steel bars, whether they are for concrete reinforcement or specialty steel, all have
a fundamental flaw in the business model: they are all commodities, yet they require
substantial capital investment in the setting up of a steel rolling mill for their
production. This invention will transform the inherent "commodity" nature of the business
into a "mass customization" business, capturing more values in the process. This invention
will allow a rolling mill to produce Cut to Length steel bars in-line and at the same
time substantially reduce end losses. It can be incorporated into any existing rolling
mill with minimum additional investment.
BACKGROUND
[0004] DE 2218041 A1 discloses apparatus and methods for producing steel bars from rolled stock of finite
lengths.
[0005] Steel bars are supplied in "standard lengths" of 12 m, 15 m, or 18 m and in "standard
bundle weights" of generally 2 ton bundles for the same size bars. In the case of
concrete-reinforcing bars, they still have to be cut into shorter lengths according
to the design of the building structure for a specific column, beam or floor slab.
These short specific lengths are generally not designed to be multiples of any standard
lengths and therefore will result in end losses when cut. Such cut-to-length operation
is normally performed in a "Cut and Bend" yard, on or off the construction site. In
a "Cut and Bend" operation, it is typical to expect a 5% loss in the steel bar ends,
even with the best computer aided optimization programs. This 5% is very substantial
in the building project, especially with the current high prices of steel bars.
[0006] The standard lengths of 12 m, 15 m and 18 m are selected to make maximum use of the
size of the cargo holds of ships and trucks, while the standard bundle weight also
serves for optimizing the capacity of the lifting apparatus of the ships and trucks.
[0007] There is an existing technology call "Flash Welding" of hot billets in which the
tail end of a billet is welded to the front end of the next billet, in-line as they
exit from the reheating furnace. Such operation will enable the rolling of bars continuously
without any end; this is similar to "sequence casting" in a continuous casting machine.
The primary objective of this process of endless rolling is to minimize the head and
tail crops in the rolling mill and the short end losses at the cooling bed. In employing
this flash welding process together with the very high accuracy of the modern flying
shear before the cooling bed, one is able to achieve an accuracy of +50/-00 mm consistently
for 120 m long bars on the cooling bed. This is about 0.05% end losses versus an industrial
norm of 2.5%.
[0008] The flash welding process produces elevated temperature at each of the flash welded
joints of the billet. Due to the temperature dependence of draft/spread characteristics,
the joints, being at a higher temperature than the rest of the billet, will have more
elongation than spread, resulting in "necking"-smaller cross sectional area than the
nominal area in the finished product. This means that the area of the joint can fall
below the minimum area specified by the Steel Standard.
U.S. Pat. No. 6,929,167 B2 Pong et al. teaches a method which will eliminate such effect of such necking. In the actual
operation, gauges were set up in the rolling line to monitor the dimension of the
steel bars and the results show that this method is able to maintain a uniform cross
section throughout the length of the bar including the flash welded joints.
[0009] With the use of flash-welding and uniform cross-section at the weld joints, "In-Line
Cut to Length" steel bars are produced by the rolling mills with no loss of Steel
bars are generally rolled from a 150 mm (6 inches) square billet of 12 meter (40 feet)
length. These billets will be rolled into finished steel bars of various diameters
from 50 mm (2 inches) to 10 mm ([3/8] inch). Because of the starting weight of the
billet is finite, it will end up with various finished lengths of the steel bars of
each diameter. The total lengths of the steel bars from each piece of billet will
not be exact multiples of the normal finished bar length of 12 m (40 feet) and one
will have end losses. This is usually 2.5%. With endless rolling as described above,
the billet is welded end to end to form a continuous infinite piece and there will
be no end losses.
[0010] In the specifications of steel bar standards BS4449 or ASTM 615, a size tolerance
is permitted, provided it does not compromise the strength of the steel bar. Typically,
BS4449 (2005) such allowable size tolerance is plus or minus 4.5%. The aim is to target
at minus 3%, i.e. a lighter bar, but without affecting the strength of the bar at
the nominal diameter. With single billet rolling, the minus 3% of the finished bar
diameter will end up with a longer end piece by the same 3%. This will go to waste.
With the endless rolling of welding the billets, the longer end piece will go into
and become part of the next incoming piece and therefore this minus 3% is completely
recovered as usable steel and is not waste.
[0011] For shipping or trucking reasons, such finished steel bars are usually cut to 12
m (40 feet), 15 m (50 feet), or 18 m (60 feet) lengths. Because of different lengths
of columns, beams or slabs, the actual length requirement at the building site is
never exactly 12 m, 15 m or 18 m. These bars have to be cut in a separate operation.
A typical end loss of cutting to specific bar lengths is 5%.
SUMMARY OF THE INVENTION
[0012] An object of the invention is to provide a method and apparatus for cutting any arbitrary
specific lengths of steel bars in line in a continuous rolling operation.
[0013] A further object of the invention is to enable such method and apparatus to continuously
produce short lengths of steel bars which would normally require interruption of the
continuous operation.
[0014] A particular object of the invention is to provide a method and apparatus which can
produce cut to length short pieces according to a customer order, in line, without
affecting rolling speed.
[0015] In accordance with the invention, this is achieved by correlating a first cut of
the continuous bar into a length which is a multiple of the short length of the finished
bar and cutting the first cut length into its multiple lengths during continuous operation
of the mill.
[0016] Thus, viewed from one aspect, the present invention provides a method of producing
steel bars that are cut to length in response to a customer order, said method comprising
the steps of: producing a continuous length of steel bar from a rolling mill, cutting
said continuous length of steel bar into successive segments, each representing a
multiple of the length of the bar of the customer order, cutting said segments in
in-line cold shears first into two times the length of the bar of the customer order
and then in half into lengths equal to the length of the bar of the customer order
while maintaining the production of the continuous length of steel bar produced by
the rolling mill, and bundling the bars of the length of the customer order for discharge
from the mill.
[0017] Viewed from another aspect, the present invention provides apparatus for producing
steel bars that are cut to length in response to a customer order, said apparatus
comprising: a rolling mill for producing a continuous length of steel bar; a flying
shear at an exit end of said rolling mill; a CPU connected to said flying shear to
cut said continuous length of steel bar into lengths each representing a multiple
of the length of the bar of the customer order; two in-line cold shears to which said
lengths are continuously fed, said cold shears having respective adjustable gauge
stops, said cold shears and said gauge stops being connected to said CPU which positions
and operates said cold shears so that one cold shear cuts said lengths into pieces
equal to two times the length of the bar of the customer order and the other cold
shear cuts the cut pieces in half to produce bars cut to the length of the customer
order, said cold shears being operated in time with the production of the continuously
produced length of bar, and a bundling station positioned to receive the cut bars
from the cold shears for producing bundles of the bars of the length of the customer
order.
[0018] The appended claims include dependent claims which define preferred embodiments of
the above aspects of the invention.
[0019] The following detailed description details exemplary embodiments of the invention,
with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWING
[0020]
FIG. 1 is a diagrammatic illustration of a portion of a steel mill in which rolled
bar is formed into cut to specific length bundles.
FIG. 2 diagrammatically shows a central processing unit (CPU) which controls operation
to form the cut to length bundles.
DETAILED DESCRIPTION
[0021] In FIG. 1 there is shown the exit end 10 of a rolling mill 11 from which rolled bar
12 is continuously discharged at a determined high rate of speed. The rolled bar 12
has been rolled from continuous billet joined front to rear and has been hot rolled
in the rolling mill. Downstream of the end 10 of the rolling mill is a flying shear
13 which is activated by a central processing unit (CPU) to cut the bar 12 on the
fly and form a cut bar 14 of a given length which is deposited on the rollers 15 of
a roller table 16.
[0022] As previously explained, current practice is limited to producing bars at the end
of the mill of lengths of about 120 m as these are the minimum lengths which the current
mill construction can be produced at the high rate of rolling speeds.
[0023] The invention permits producing specific arbitrary shorter lengths without reducing
the production rate and in particular cutting the length of the bars to the customer
order in correspondence to the length needed on the job thereby completely eliminating
end cut waste on the job site as well as the need for production cutting at the job
site. This will be explained more fully later.
[0024] The cut bar 14 is then displaced laterally into a notch in a cooling bed 16 to undergo
cooling. The bar 14 is advanced stepwise, notch by notch until it reaches the last
notch where it is now cooled and ready to be displaced laterally to a shuffle device
SD where a given number of bars e.g 10 or so are collected and formed in a layer of
a batch of bars 14.
[0025] The construction and operation of the cooling bed and shuffle device is conventional
and not described in detail.
[0026] The batch of bars 14 on the shuffle device are then moved sideways onto a roller
table 17 disposed adjacent to the shuffle device SD. The roller table 17 has rollers
18 which are driven to advance the batch 14 of bars in reverse to the direction it
was advanced on the roller table 17.
[0027] In order to keep up with the production rate and make the short cut-to-length cuts,
two cold shears 19,20 and respective movable gauges 21, 22 are placed in sequence
along the roller table 17 to cut the bars 14 into the desired lengths. The cold shears
are massive in size to develop forces of 1000 tons or more and they are fixedly secured
in a rigid foundation. The two cold shears are secured at a spacing of 20 meters to
handle the largest contemplated cut-to-length size. Specifically, the bars 14 are
moved to a stopped position controlled by the gauge 21 at which cold shears 19 is
spaced at a distance from the end of the bars by an amount equal to twice the length
of the desired cut-to-length piece. The cut pieces advance to the gauge 22 at which
the cold shear 20 cuts the pieces in half to the final desired length. When both cold
shears 19, 20 have cut the bars, there are pieces 23 equal to the desired cut length.
The movable gauges 21, 22 permit adjustment of the position at which the cold shears
cut the bars 14 to change the length of the pieces to be cut. By this double cut of
the bars, the rate of production can be maintained. Also, when the length of the cut
pieces is to be changed for a subsequent batch, the movable gauges are adjusted to
correspond to the desired new length.
[0028] The cut to length pieces are next moved sideways to a bundling station 24 where the
pieces 23 are bundled and made ready for shipment.
[0029] The bundling station 24 includes a roller table 25 on which the cut pieces 23 are
deposited. The pieces 23 advance into a conventional collector 26 where rollers are
arranged in a predominantly circular array to collect the pieces in a circular bundle.
[0030] In order to tie the bundle of cut pieces when they are of short length i.e. of substantially
less than 12 m e.g. 8 m or less, three spaced ties are needed. When the length of
the short pieces is changed based on a new customer order, the spacing or pitch of
the ties must be changed correspondingly. Furthermore, according to the invention,
the tying operation is carried out in one stop to keep up with the mill speed. Generally,
two end ties are made at a given distance from the ends of the bundle and a central
tie is made midway therebetween. The collected pieces are fed into three spaced conventional
bundlers 27, 28, 29 which tie the bundle of pieces at ties 30, 31, 32 at appropriate
spaced locations. The ties 30, 31, and 32 are made simultaneously and the bundle is
then advanced from the bundling station 24.
[0031] In accordance with the invention, the first and third bundlers 27 and 29 are movably
supported so that they can be quickly adjusted to adjust the space when the length
of the cut piece is changed. The movable bundlers 27, 29 are drivingly connected to
respective hydraulic cylinders 33, 34 which are connected to the CPU to control the
position of the bundlers.
[0032] The invention makes it possible to be able to provide cut to specific short lengths
required by the building site and recover all the losses associated with existing
technology and at the same time, does not slow down the production of the mill.
[0033] A key component of the invention is the CPU which controls with the charging of the
billets, the following elements.
- a) flying shears 13
- b) rake and shuffle bars
- c) roller table 17
- d) roller table 25
- e) cold shears 19, 20
- f) gauge stops 21, 22
- g) bundlers 27, 28, 29
- h) hydraulic cylinders 33, 34
Example
[0034] The following Example will explain in detail the operation of the mill to obtain
cut-to-length bars.
[0035] The weight of each billet is recorded as it is being charged into the reheat furnace.
These charge weights will be compared with the end product weights to obtain material
losses for that shift, which will primarily be oxidation losses. There will be minimal
front end crop losses and no tail end crop losses because of the use of the flash
welding process as explained previously.
[0036] The operator keys in the exact number and exact specific lengths as per the order
of that particular size of bar being rolled for the command of the flying shear 13.
[0037] With conventional methods;
[0038] If one were to cut for an order of 6.4 m bar from a standard length of 12 m, one
will end up with a 6.4 m bar and a short piece of 5.6 m.
[0039] If it were to cut from a standard length of 15 m, it will have two pieces of 6.4
m and a short piece of 2.2 m.
[0040] If it were to cut from a standard length of 18 m, it will have two pieces of 6.4
m with a short piece of 5.2 m.
[0041] These short lengths are usually kept on the side for another part of the building
project which may require a length shorter than these end cuts, or they will be disposed
of as scrap. All these options are undesirable.
[0042] With the invention, the operator will set in the programable logic of the CPU sequence
for the flying shears 13 to produce lengths of cut as multiples of the specific lengths
of the final product. Assuming that a typical cooling bed is able to accept 120 m
long bars, the programable logic at the CPU will allow the operator to set the flying
shear to cut lengths of 115.2 m, which is 18 multiples of 6.4 m. If the order is for
500 pieces of 6.4 m, the setting will be 27 cuts of 115.2 m with the last cut of 89.6
m, making a total length of 3,200 m or 500 pieces of 6.4 m.
[0043] A command signal to the cooling bed will move a double step after the last cut of
89.6 m to separate this batch from the next.
[0044] If the next order is for 5.2 m, the operator will input 109.2 m, which makes 21 pieces
of 5.2 m to follow the previous 6.4 m batch. If this order of 5.2 m is, for example,
400 pieces, the number of cuts for 109.2 m, will be 18, with the last cut at 114.4
m. The total length of this order is 2,080 m making 400 pieces of 5.2 m finished length.
Again a double step motion of the cooling bed will separate this new batch from the
next. The same process will be repeated for any other specific lengths and quantities
for the same size bar.
[0045] As each batch of bars leaves the cooling bed 16 by the raking motion and the shuffle
bars the batch of bars will be side shuffled to roller table 17 in the conventional
way. Each batch will be conveyed separately to the cold shears 19, 20 for final cutting
to the ordered lengths. In this case, the first batch will be 115.2 m with the last
piece 89.6 m, for a final cut length of 6.4 m and the second batch will be 109.2 m
with the last piece 114.4 m, for the final cut length of 5.2 m. The cutting capacity
of the cold shear will determine how many bars from the same batch length are presented
for cutting each time. It is worth noting that since the tail end of each bar running
to the cooling bed is being run in reverse direction to the cold shears, these tail
ends having been cleanly cut by the flying shears 13 will not require head trimming
by the cold shears. This contributes to additional material saving.
[0046] Two stationary in-line cold shears 19, 20 are utilized in order to keep up with the
rolling capacity of the mill for the cutting of such short bars. Each cold shear will
have its respective movable gauges stop 21, 22. In this example, the first a gauge
stop 21, will be set for 12.8 m, which is 2*6.4 m, and the cut bars will move along
to the next gauge stop 24 which has been set for 6.4 m and are cut to 6.4 m by the
second cold shear. After completing each batch of specific lengths, the gauge stops
21, 22 will be moved automatically by a signal from the CPU to the next required length
and locked. In this example, the first gauge stop 21 will move to 10.4 m, which is
2*5.2 m, while the second gauge stop 22 will move to 5.2 m.
[0047] Steel bars of each specific length will be collected separately in a conventional
manner and tied into bundles in bundle weights convenient for handling. Additional
commands in the programable logic of the CPU will be sent to the in-line bundlers
27, 28, 29 so that the ties will be made at the appropriate spaced positions along
the length of the short bars. The first and third bundlers 27, 29 are movable and
the central bundler 28 is fixed so as to set the proper pitch for the ties and enable
all ties to be made simultaneously. Each tied bundle is weighed and tagged with the
appropriate bar code label specifying contract number, size, length, number of pieces
and bending schedules. It may be necessary to install more bundling stations to increase
the bundling capacity for such short bars to match that of the production capacity
of the mill.
[0048] In a separate operation, these bundles of specific length are transferred to a bending
yard near the mill. This bending yard will make the necessary bending of each of the
bars to a bending bar schedule. These cut and bend bars will then be ready to be delivered
to the construction site for installation in the various beams or columns or slabs.
[0049] In total, the rolling operation of the invention should save as much as 10% of losses
in conventional manufacture and be able to supply cut to length bars in a specific
number to customers with no additional cost.
[0050] Although the invention has been described with reference to a disclosed embodiment,
it will become apparent to those skilled in the art that numerous modifications and
variations can be made within the scope of the invention as defined in the claims.
1. A method of producing steel bars that are cut to length in response to a customer
order, said method comprising the steps of:
producing a continuous length of steel bar from a rolling mill,
cutting said continuous length of steel bar into successive segments, each segment
representing a multiple of the length of the bar of the customer order,
cutting said segments in in-line cold shears first into two times the length of the
bar of the customer order and then in half into lengths equal to the length of the
bar of the customer order while maintaining the production of the continuous length
of steel bar produced by the rolling mill, and
bundling the bars of the length of the customer order for discharge from the mill.
2. A method as claimed in claim 1, wherein when a change of length of the bar by a customer
order is made, the length of said segments is changed and said segments are repositioned
relative to said cold shears to produce the bar length corresponding to the changed
length of the customer order.
3. A method as claimed in claim 2, wherein a CPU controls the cutting of the continuous
length of steel bar by a flying shear and the cutting of the bar by the in-line cold
shears.
4. A method as claimed in claim 3, comprising adjusting the position of said segments
relative to said cold shears to cut the segments to the desired lengths in response
to signals from said CPU.
5. A method as claimed in claim 4, wherein the bundling of the steel bars is effected
in simultaneously in three in-line bundlers, one of which is stationary and the other
two of which are moved to position in response to a signal from said CPU.
6. A method as claimed in claim 4, wherein said cold shears have respective gauge stops,
said CPU producing signals to move said gauge stops to positions at which the cold
shears cut the segments to the desired length of the customer order.
7. Apparatus for producing steel bars that are cut to length in response to a customer
order, said apparatus comprising:
a rolling mill for producing a continuous length of steel bar;
a flying shear at an exit end of said rolling mill;
a CPU connected to said flying shear to cut said continuous length of steel bar into
lengths each length representing a multiple of the length of the bar of the customer
order;
two in-line cold shears to which said lengths are continuously fed,
said cold shears having respective adjustable gauge stops,
said cold shears and said gauge stops being connected to said CPU which positions
and operates said cold shears so that one cold shear cuts said lengths into pieces
equal to two times the length of the bar of the customer order and the other cold
shear cuts the cut pieces in half to produce bars cut to the length of the customer
order,
said cold shears being operated in time with the production of the continuously produced
length of bar, and
a bundling station positioned to receive the cut bars from the cold shears for producing
bundles of the bars of the length of the customer order.
8. Apparatus as claimed in claim 7, wherein said bundling station includes three in-line
bundlers, the first and third being movable and the second stationary.
9. Apparatus as claimed in claim 8, wherein said first and third bundlers are connected
to the CPU for being moved in response to a change in length of the bar of the customer
order.
1. Verfahren zur Produktion von Stahlstäben, die als Reaktion auf einen Kundenauftrag
abgelängt werden, wobei besagtes Verfahren folgende Schritte umfasst:
Produzieren einer kontinuierlichen Länge von Stahlstab ab einem Walzwerk,
Schneiden besagter kontinuierlichen Länge von Stahlstab in aufeinanderfolgende Segmente,
wobei jedes Segment ein Vielfaches der Länge des Stabs des Kundenauftrags repräsentiert,
Schneiden der besagten Segmente in In-Line-Kaltscheren zuerst in zweimal die Länge
des Stabs des Kundenauftrags und dann in die Hälfte in Längen gleich der Länge des
Stabs des Kundenauftrags, während Aufrechterhaltung der Produktion der kontinuierlichen
Länge des vom Walzwerk produzierten Stahlstabs, und
Bündeln der Stäbe der Länge des Kundenauftrags zum Austrag aus dem Walzwerk.
2. Verfahren wie in Anspruch 1 beansprucht, wobei, wenn eine Änderung der Länge des Stabs
durch einen Kundenauftrag vorgenommen wird, die Länge des besagten Segments geändert
wird und besagte Segmente relativ zu besagter Kaltschere neu positioniert werden,
um die Stablänge zu produzieren, die der geänderten Länge des Kundenauftrags entspricht.
3. Verfahren wie in Anspruch 2 beansprucht, wobei eine CPU das Schneiden der kontinuierlichen
Länge des Stahlstabs durch eine fliegende Schere und das Schneiden des Stabs durch
die In-Line-Kaltscheren steuert.
4. Verfahren wie in Anspruch 3 beansprucht, das Einstellen der Position der besagten
Segmente relativ zu besagter Kaltschere zum Schneiden der Segmente auf die erwünschten
Längen als Reaktion auf Signale der besagten CPU umfasst.
5. Verfahren wie in Anspruch 4 beansprucht, wobei das Bündeln der Stahlstäbe gleichzeitig
in drei In-Line-Bündelmaschinen bewirkt wird, wovon eine stationär ist und die zwei
anderen als Reaktion auf ein Signal von der CPU in Position bewegt werden.
6. Verfahren wie in Anspruch 4 beansprucht, wobei die besagten Kaltscheren jeweilige
Messanschläge aufweisen, besagte CPU Signale produziert, um besagte Messanschläge
in Positionen zu bewegen, in denen die Kaltscheren die Segmente auf die erwünschte
Länge des Kundenauftrags schneiden.
7. Vorrichtung zur Produktion von Stahlstäben, die als Reaktion auf einen Kundenauftrag
abgelängt werden, wobei besagte Vorrichtung umfasst:
ein Walzwerk zum Produzieren einer kontinuierlichen Länge von Stahlstab;
eine fliegende Schere an einem Ausgangsende des besagten Walzwerks;
eine CPU, die an besagte fliegende Schere angeschlossen ist, um besagte kontinuierliche
Länge von Stahlstab in Längen zu schneiden, wobei jede Länge ein Vielfaches der Länge
des Stabs des Kundenauftrags repräsentiert,
zwei In-Line-Kaltscheren, denen besagte Längen kontinuierlich zugeführt werden,
wobei besagte Kaltscheren jeweilige einstellbare Messanschläge aufweisen,
wobei besagte Kaltscheren und besagte Messanschläge an besagte CPU angeschlossen sind,
welche die besagten Kaltscheren positioniert und betreibt, sodass eine Kaltschere
die besagten Längen in Stücke gleich zweimal der Länge des Stabs des Kundenauftrags
schneidet und die andere Kaltschere die geschnittenen Stücke in die Hälfte schneidet,
um Stäbe zu produzieren, die auf die Länge des Kundenauftrags geschnitten sind,
wobei die besagten Kaltscheren zeitgleich mit der Produktion der kontinuierlich produzierten
Länge von Stab betrieben werden, und
eine Bündelstation, die positioniert ist, die geschnittenen Stäbe von den Kaltscheren
zu empfangen, um Bündel von Stäben der Länge des Kundenauftrags zu produzieren.
8. Vorrichtung wie in Anspruch 7 beansprucht, wobei die besagte Bündelstation drei In-Line-Bündelmaschinen
einschließt, wobei die erste und die dritte Maschine verschiebbar sind und die zweite
Maschine stationär ist.
9. Vorrichtung wie in Anspruch 8 beansprucht, wobei die besagten ersten und dritten Bündelmaschinen
an die CPU angeschlossen sind, um als Reaktion auf eine Längenänderung des Stabes
des Kundenauftrags verschoben zu werden.
1. Procédé de production de barres d'acier qui sont coupées en longueur en réponse à
une commande de client, ledit procédé comportant les étapes consistant à :
produire une longueur continue de barre d'acier dans un train de laminage,
découper ladite longueur continue de barre d'acier en segments successifs, chaque
segment représentant un multiple de la longueur de la barre de la commande du client,
découper lesdits segments dans des cisailles de découpage à froid en ligne tout d'abord
en deux fois la longueur de la barre de la commande du client puis en deux en longueurs
égales à la longueur de la barre de la commande du client tout en maintenant la production
de la longueur continue de barre d'acier produite par le train de laminage, et
mettre en lots les barres de la longueur de la commande du client à des fins de décharge
en provenance du train de laminage.
2. Procédé selon la revendication 1, dans lequel, quand il y a un changement de longueur
de la barre par une commande de client, la longueur desdits segments est changée et
lesdits segments sont repositionnés par rapport auxdites cisailles de découpage à
froid pour produire la longueur de barre correspondant à la longueur changée de la
commande du client.
3. Procédé selon la revendication 2, dans lequel une unité centrale commande la découpe
de la longueur continue de barre d'acier par une cisaille volante et la découpe de
la barre par les cisailles de découpage à froid en ligne.
4. Procédé selon la revendication 3, comportant l'étape consistant à ajuster la position
desdits segments par rapport auxdites cisailles de découpage à froid pour découper
les segments selon les longueurs souhaitées en réponse aux signaux provenant de ladite
unité centrale.
5. Procédé selon la revendication 4, dans lequel l'étape consistant à mettre en lots
les barres d'acier est effectuée de manière simultanée dans trois installations de
mise en lots en ligne, dont l'une est fixe et dont les deux autres sont déplacées
jusque sur une position en réponse à un signal provenant de ladite unité centrale.
6. Procédé selon la revendication 4, dans lequel lesdites cisailles de découpage à froid
ont des butées de contrôle respectives, ladite unité centrale produisant des signaux
pour déplacer lesdites butées de contrôle jusque sur des positions où les cisailles
de découpage à froid découpent les segments selon la longueur souhaitée de la commande
du client.
7. Appareil permettant de produire des barres d'acier qui sont coupées en longueur en
réponse à une commande de client, ledit appareil comportant :
un train de laminage destiné à produire une longueur continue de barre d'acier ;
une cisaille volante au niveau d'une extrémité de sortie dudit train de laminage ;
une unité centrale connectée à ladite cisaille volante pour découper ladite longueur
continue de barre d'acier en longueurs, chaque longueur représentant un multiple de
la longueur de la barre de la commande du client ;
deux cisailles de découpage à froid en ligne dans lesquelles lesdites longueurs sont
alimentées en continu,
lesdites cisailles de découpage à froid ayant des butées de contrôle ajustables respectives,
lesdites cisailles de découpage à froid et lesdites butées de contrôle étant connectées
à ladite unité centrale qui positionne et actionne lesdites cisailles de découpage
à froid de sorte qu'une cisaille de découpage à froid découpe lesdites longueurs en
pièces égales à deux fois la longueur de la barre de la commande du client et l'autre
cisaille de découpage à froid découpe les pièces découpées en deux pour produire des
barres coupées selon la longueur de la commande du client,
lesdites cisailles de découpage à froid étant actionnées en même temps que la production
de la longueur de barre produite en continu, et
une station de mise en lots positionnée pour recevoir les barres découpées en provenance
des cisailles de découpage à froid en vue de produire des lots des barres de la longueur
de la commande du client.
8. Appareil selon la revendication 7, dans lequel ladite station de mise en lots comprend
trois installations de mise en lots en ligne, la première et la troisième étant mobiles
et la seconde fixe.
9. Appareil selon la revendication 8, dans lequel les première et troisième installations
de mise en lots sont connectées à l'unité centrale à des fins de déplacement en réponse
à un changement de longueur de la barre de la commande du client.