GB1569196A - Slitting a multi-stranded bar - Google Patents

Description

(54) SLITTING A MULTI-STRAND BAR (71) We, CO-STEEL INTERNATIONAL LIMITED, 1400 Hopkins Street, Whitby, Ontario, Canada, a Canadian corporation, do hereby declare the invention, for which we pray that a patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following statement This invention relates to a method of slitting billets of metal which are rolled to produce a double or a triple stranded bar, and to the elongated metal bars produced thereby.

In the high speed production of steel bars or other elongated metal bars a heated billet is passed through a series of reducing rolls.

In this process only a certain production can be achieved at any predetermined delivery speed. To increase production for a given speed of delivery a technique has been developed of rolling a billet to form two or more strands interconnected by a continuous node or nodes and then slitting the bar by passing the node or nodes longitudinally over the edge of fixed knives. Such knives are, however, subject to heavy wear and must be replaced frequently, causing expense and loss of production time. This wear can be minimised by using rotating knives or knife-like rolls which do not substantially change the shape or cross-sectional area of the bars. However, such wear cannot be eliminated.

It has been known to separate interconnected strands by passing them between a pair of opposing rolls which cause adjacent strands to be offset vertically relative to one another, thereby shearing the node or web and separating the strands. This method may result in a product of inferior quality.

It has also been known to separate interconnected strands by passing them between a pair of rolls which reduce the cross-sectional area of adjacent strands by different amounts thus causing them to exit from the roll stand at different velocities, the speed differential in turn inducing a longitudinal force in the node which results in ruptures and strand separation. This method is not well suited to modern continuous rolling mills because the separated strands are not presented to subsequent stands in the desired form, namely simultaneously and at substantially identical velocities. Furthermore, this method can only be used in a mill which is equipped with twin looping tables.

According to the present invention, there is provided, in the production of elongated metal bars from billets in which the billet is passed between the opposed rolls of successive mill stands whereby a compressive force is applied to the billet, a method of slitting a multi-stranded bar of no more than three strands wherein each strand is interconnected to the adjacent strand at a continuous node, comprising the step of passing the bar through the opposed rolls of at least one mill stand to reduce the cross-sectional area of the strands by equal percentages, applying to said bar in said at least one mill stand a compressive working force so as to produce said equal cross-sectional area reduction on each of said strands and create lateral tensile forces in each connecting node causing each of said nodes to rupture and causing a laterally outward shift of the centres of gravity of the outermost of said strands substantially simultaneously with the creation of said lateral tensile forces, thereby separating adjacent strands.

An example embodiment of the invention is shown in the accompanying drawings in which: Figure 1 is a flow diagram showing an example sequence of stands which are sets of rolis having grooves or "passes" o; different cross-sectional shapes for reducing a billet to a double stranded bar, separating or slitting the strands longitudinally, and shaping the separated strands.

Figure 2 is a schematic diagram showing the cross-sectional shape of the double stranded bar as it enters the third stand of Figure 1 superimposed on the same bar as it reaches the centre line of the rolls of the third stand.

As seen in Figure 1 of the drawings, a billet of metal is passed through a series of mill stands each having a set of opposed rolls which first reduce the billet to a double stranded bar and then split the double stranded bar into two separate strands. The opposed rolls of further stands reduce the two separated strands to bars of desired cross-sectional dimensions.

In the example illustrated by Figure 1, a billet 10 passing between a first pair of opposed rolls 12 of a first stand A is reduced in cross-sectional area and a bar 10 having a substantially square cross-sectional shape is produced. After leaving stand A, bar 10 passes into a second stand B between a second pair of opposed rolls 14 each having a centrally disposed collar 15 whereby bar 10 is further reduced and reshaped into a double stranded bar 16 having a pair of parallel strands 18 equal in area and interconnected at a node 20. From rolls 14 of stand B, double stranded bar 16 is passed into a third stand C between a third pair of opposed rolls 22 each having a centrally disposed collar 23, which further reduces the cross-sectional area of the bar, reducing the cross-sectional area of the strands by equal percentages.

The pass between rolls 22 is both shallower and wider than strands 16 entering stand C from stand B, and the strands are flattened to produce strands 18. The centres of gravity of the two strands are shifted away from each other. In Figure 2, outline X represents the cross-sectional shape of the double stranded bar as it enters stand C of Figure 1 after passing from stand B, and outline Y represents the cross-sectional shape of the same bar as it reaches the centre line of the rolls of stand C. By such working the centre of gravity of such strand 1 8 in cross-section X, represented by numeral CGl, is shifted to location CG2 in cross-section Y. In so doing, the material of strands 18 closest to node 20 is elongated more than is the material adjacent the outer edges of the strands. This greater elongation closer to node 20 causes strands 18 to tend to diverge, creating lateral tensile forces in the node. These forces cause rupture and thus separation of the strands.

After leaving rolls 22, strands 18 in the example embodiment pass separately through a stand D having a pair of opposed reducing rolls 24 and further through a stand E having a pair of opposed reducing rolls 26 to produce finished bars 28.

It will be appreciated that stands A to E are not the only stands in the mill; for example roughing stands may precede stand A.

To produce separate strands from a three stranded bar the same procedure is followed as in the previously described example embodiment except that the elongation of the middle strand of the bar is uniform across it while there is an elongation gradient in the two outer strands. This causes the two outer strands to diverge from the middle strand and separate at their interconnecting nodes.

It has been found preferable to provide collars 15 of rolls 14 and collars 23 of rolls 22 of a wedge-shaped configuration. As illustrated in Figure 1, each collar 15 preferably forms an included angle greater than the included angle of each collar 23. In a specific example each collar 15 forms an included angle of approximately ninety degrees (90 ) at its apex and the apex is rounded with a radius of about one-eigth of an inch (1/8") the thickness of the gap between the two collars and the resulting thickness of the node 20 being about onehalf the thickness of the strands 1 8 as the bar leaves stand B, while each collar 23 preferably forms an included angle of approximately sixty degrees (60 ) at its apex and the apex is rounded with a radius of about one thirtysecond of an inch (1/32"), the width of the gap between these two collars being about twenty thousandths of an inch (0.02"). It will be appreciated that it is node 20, which in this example is approximately 0.02" in thickness, which must be torn to separate strands 18.

Of course the speed of travel of the bar, the chemistry of the bar and the temperature of the bar in addition to the above-mentioned pass configuration, may effect the separation of the strands. In particular it will be appreciated that an unduly slow speed of travel will inhibit the operation of the invention.

However, speed will be understood as a relative term which will differ with the bar size and pass configuration.

WHAT WE CLAIM IS: 1. In the production of elongated metal bars from billets in which the billet is passed between the opposed rolls of successive mill stands whereby a compressive force is applied to the billet, a method of slitting a multistranded bar of no more than three strands wherein each strand is interconnected to the adjacent strand at a continuous node, comprising the step of passing the bar through the opposed rolls of at least one mill stand to reduce the cross-sectional area of the strands by equal percentages, applying to said bar in at least one mill stand a compressive working force so as to produce said equal crosssectional area reduction on each of said strands and create lateral tensile forces in each connecting node causing each of said nodes to rupture and causing a laterally outward shift of the centres of gravity of the outermost of said strands substantially simultaneously with the creation of said lateral tensile forces, thereby separating adjacent strands.

2. A method according to Claim 1, wherein the bar is passed through at least two mill stands, the passage through the first stand

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (4)

**WARNING** start of CLMS field may overlap end of DESC **. stranded bar as it enters the third stand of Figure 1 superimposed on the same bar as it reaches the centre line of the rolls of the third stand. As seen in Figure 1 of the drawings, a billet of metal is passed through a series of mill stands each having a set of opposed rolls which first reduce the billet to a double stranded bar and then split the double stranded bar into two separate strands. The opposed rolls of further stands reduce the two separated strands to bars of desired cross-sectional dimensions. In the example illustrated by Figure 1, a billet 10 passing between a first pair of opposed rolls 12 of a first stand A is reduced in cross-sectional area and a bar 10 having a substantially square cross-sectional shape is produced. After leaving stand A, bar 10 passes into a second stand B between a second pair of opposed rolls 14 each having a centrally disposed collar 15 whereby bar 10 is further reduced and reshaped into a double stranded bar 16 having a pair of parallel strands 18 equal in area and interconnected at a node 20. From rolls 14 of stand B, double stranded bar 16 is passed into a third stand C between a third pair of opposed rolls 22 each having a centrally disposed collar 23, which further reduces the cross-sectional area of the bar, reducing the cross-sectional area of the strands by equal percentages. The pass between rolls 22 is both shallower and wider than strands 16 entering stand C from stand B, and the strands are flattened to produce strands 18. The centres of gravity of the two strands are shifted away from each other. In Figure 2, outline X represents the cross-sectional shape of the double stranded bar as it enters stand C of Figure 1 after passing from stand B, and outline Y represents the cross-sectional shape of the same bar as it reaches the centre line of the rolls of stand C. By such working the centre of gravity of such strand 1 8 in cross-section X, represented by numeral CGl, is shifted to location CG2 in cross-section Y. In so doing, the material of strands 18 closest to node 20 is elongated more than is the material adjacent the outer edges of the strands. This greater elongation closer to node 20 causes strands 18 to tend to diverge, creating lateral tensile forces in the node. These forces cause rupture and thus separation of the strands. After leaving rolls 22, strands 18 in the example embodiment pass separately through a stand D having a pair of opposed reducing rolls 24 and further through a stand E having a pair of opposed reducing rolls 26 to produce finished bars 28. It will be appreciated that stands A to E are not the only stands in the mill; for example roughing stands may precede stand A. To produce separate strands from a three stranded bar the same procedure is followed as in the previously described example embodiment except that the elongation of the middle strand of the bar is uniform across it while there is an elongation gradient in the two outer strands. This causes the two outer strands to diverge from the middle strand and separate at their interconnecting nodes. It has been found preferable to provide collars 15 of rolls 14 and collars 23 of rolls 22 of a wedge-shaped configuration. As illustrated in Figure 1, each collar 15 preferably forms an included angle greater than the included angle of each collar 23. In a specific example each collar 15 forms an included angle of approximately ninety degrees (90 ) at its apex and the apex is rounded with a radius of about one-eigth of an inch (1/8") the thickness of the gap between the two collars and the resulting thickness of the node 20 being about onehalf the thickness of the strands 1 8 as the bar leaves stand B, while each collar 23 preferably forms an included angle of approximately sixty degrees (60 ) at its apex and the apex is rounded with a radius of about one thirtysecond of an inch (1/32"), the width of the gap between these two collars being about twenty thousandths of an inch (0.02"). It will be appreciated that it is node 20, which in this example is approximately 0.02" in thickness, which must be torn to separate strands 18. Of course the speed of travel of the bar, the chemistry of the bar and the temperature of the bar in addition to the above-mentioned pass configuration, may effect the separation of the strands. In particular it will be appreciated that an unduly slow speed of travel will inhibit the operation of the invention. However, speed will be understood as a relative term which will differ with the bar size and pass configuration. WHAT WE CLAIM IS:

1. In the production of elongated metal bars from billets in which the billet is passed between the opposed rolls of successive mill stands whereby a compressive force is applied to the billet, a method of slitting a multistranded bar of no more than three strands wherein each strand is interconnected to the adjacent strand at a continuous node, comprising the step of passing the bar through the opposed rolls of at least one mill stand to reduce the cross-sectional area of the strands by equal percentages, applying to said bar in at least one mill stand a compressive working force so as to produce said equal crosssectional area reduction on each of said strands and create lateral tensile forces in each connecting node causing each of said nodes to rupture and causing a laterally outward shift of the centres of gravity of the outermost of said strands substantially simultaneously with the creation of said lateral tensile forces, thereby separating adjacent strands.

2. A method according to Claim 1, wherein the bar is passed through at least two mill stands, the passage through the first stand

forming a double stranded bar from a billet with a first included angle between the strands at the node thereof, the passage through the second mill stand reducing the cross-sectional area of each strand with a second included angle between the strands at the node thereof, said first included angle being greater than said second included angle.

3. In the high speed production of elongated metal bars, a method of slitting a mult-stranded bar, the method being substantially as hereinbefore described with reference to, and as schematically illustrated in, the accompanying drawings.

4. An elongated metal bar, whenever produced by a method in accordance with any one of Claims 1 to 3.