US2050298A

US2050298A - Metal reducing method

Info

Publication number: US2050298A
Application number: US17316A
Authority: US
Inventors: Everett Samuel James
Original assignee: Thos Firth & John Brown Ltd
Current assignee: Thos Firth & John Brown Ltd; THOS FIRTH and JOHN BROWN Ltd
Priority date: 1934-04-25
Filing date: 1935-04-19
Publication date: 1936-08-11
Anticipated expiration: 1953-08-11

Description

Aug. 1l, 1936. s 1 EvERr-:TT

METAL REDUCING METHOD Filed April 19, 1935 vwd?,

Patented Aug. 11, 1936 acetate Marsi, anatema rm'rnon Samuel James Everett, London, England, as

signor to Thos. Firth & John Brown limited, Sheiieid, England, a British company v Application April i9, 1935. Serial No. 17,316

lin Great Britain April 25, i934 Y is creams.' (ci, 20s- 21) This invention relates to processes for reducing metal rods, wires, strips and the like by dra ing, rolling and analogous operations.

The invention is concerned with a process of the type in which a plurality of elements (rods, Wires, strips or the like) each of which is to be reduced as aforesaid, is made up as a bundle, i. e. in side-by-side relationship held together, for example -by an encasing tube or binding, and

then subjected, i. e. as a unit, to drawing, rolling or analogous operations. The present invention provides a process for the production of fine wires by reduction from elements of larger cross section, which comprises the steps of assembling a plurality of said elements in side-by-side relationship, enclosing the assembly of elements in a tubular casing, inserting a packing material within the casing, reducing the bundle thus formed as a unit and then removing the casing' and packing material and separating the individual reduced wires.

The term matrix as used in this specification is intended to mean a support for the surfaces of the indivdual Velements oi the bundle which distributes pressure applied to the outside of the encasing tube substantially evenly-over the surfaces of the individual elements either throughout the reduction process, or at least during apart of that process, and thereby assists in limiting any distortion of the shape of the elements. The matrix may be formed, for example, by employing a large proportion (e. g. 22% by volume) of packing of a pulverulent or plastic nature, by so shaping the individual elements that they form a support for one another, by embedding the elements in metallic packing introduced into the encasing tube or binding in molten form, or by encasing each of the elements in individual tubes of a material which, during reduction, will readily deform to fill up the interstices in the assembled bundle. When the elements are so shaped as to form their own matrix they may be arranged to t together without interstices and may all be of similar cross-section and conform to a regular straight-sided polygon-e. g. a square or a hexagon.

.According to another feature of the invention, and for the purpose of facilitating the separation of the encasing tube after the reduction process has been completed, the bundle may be bound helically with a wire or the like prior to insertion in the encasing tube, so that in the assembly the inner'surface of the tube will be separated vfrom the bundle by the binding wire.

Some examples embodying features of the invention will now be described with reference to the accompanying diagrams, in which:-

Figure 1 is a cross-section showing a bundle oi. rods of circular cross-section in an encasing tube;

Figure 2 is a section showing the deformation 5 in the section of the individual rods after reduction;

Figure 3 is a cross-section showing one method of providing a matrix according to the invention;

4Figure 4 shows an alternative form of matrix; 10

Figure 5 shows another form of the invention in which the matrix for one element is formed by the contiguous sides of adjacent elements;

Figure 6 is a view illustrating the use of a helical binding between the bundle and the en- 15 casing tube;

Figure 7 is a section illustrating a further example of the invention, and

Figure 8 is a section illustrating the application of the process to the reduction of sheets. 2o

Like reference numerals indicate like partsin the various figures.

In Figure l a number of rods i@ of circular cross-section are shown packed in an encasing tube il. If a composite billet is made up in this 25 way and subjected to reduction, for example by drawing or rolling, the radial compression will tend towards deformation in the cross-section oi the rods in directions towards the interstices as indicated in Figure 2. 'I'he nature and extent 30 of the distortion varies somewhat according to the location of the individual elements with respect to the circumference of the tube.

For the purpose of minimizing the degree of distortionthe invention, according to the ex- 35 ample shown in Figure 3, makes use of a packing material of a pulverulent or plastic nature, such as French chalk or'metal in powdered form as a separating medium between the individual elements of the bundle. As shown, the rod-like 40 elements I 0 are located in separated relationship within an outer tube Il and the interstices are completely iilled in by a packing I2 of the above kind. 'Ihe packing l2 not only limits the degree of distortion of the sections, but prevents 45 the elements from becoming welded together during reduction and thereby facilitates the splitting up of the bundle when the reducing process has been completed.

In the example shown in Figure 4 each rod- 50 like element I0 is separately enclosed in a tubular -metal sheath I3, and all the elements are then inserted in bundle form within an encasing tube H Here again a matrix is provided for each element.

of the bundle. Preferably the sheath I3 is of a 55 metal (e. g. copper) which is substantially more 'ductile than that of which the elements l@ are ponent elements.

composed., so that during the initial stage or stages of the reduction process, the sheaths will be deformed to nil in the interstices in the structure. If desired, a packing material in powdered form may also be used. In this example it will be appreciated that upon completion of the reduction process, and after the encasing tub-e ll has been removed, each element has to be separated ,from its protective sheath lil. This can readily be done by dissolving with acid, the selection of the metal for the sheath being made with this end in View. Alternatively if a coated wire is desired the sheath i3 may be left in position.

In the example illustrated in Figure 5 the individual elements l@ are all of hexagonal crosssection, so that they may be assembled, as shown, in intertting relationship, the matrix for each element being formed by the contiguous faces of adjacent elements. The bundle is as before enclosed in an outer tube ll and a packing materia-l l2 is located between the periphery of the bundle and the inner wall of the encasing tube, This packing material may, for example, be French chalk, plaster of Paris or powdered metal, or molten metal may be run into the tube to form the packing. Further packing, such as French chalk, is also introduced between the adjacent faces of the individual elements in order to assist in the final splitting up of the bundle into its com- This example of the invention may be carried out with bars of any desired crosssection which interit to form a solid cross-section and the elements need not all be of the same cross-section. Thus rectangles oi" different dimensions may be used for the different elements or round sections in conjunction with four-sided concave sided sections may be employed. A further example is the combination with square sections oi octagonal sections.,

ln certain cases it may not be desirable or convenient to use a chemical orlelectroiytic method of removing the encasing tube l l after reduction, and in such cases the arrangement illustrated in Figure 6 may advantageously be employed. lite-- ferring to that figure the individual rods or wires l@ are made up in a bundle as before with a separating medium such as graphite between the individual elements, and the bundle prior to insertion in thev outer casing il is helically bound with a metal wire or strip lll. After reduction the tube l l may be cut longitudinally by a machining operation without damaging the drawn elements, since the latter are protected byl the binding lll. After the tube il has been removed, the wire [bl can be unwound and the individual elements exposed. ln some cases where a helical binding is employed this may entirely replace the outer encasing tube Il l, the bound bundle being subjected direct to the reducing operations.

In the arrangement shown in Figure l the individual rods are inserted in longitudinal holes l5 drilled in a solid billet. ln this case the interior portion ci? the billet constitutes the matrices for the individual elements, and the circumferential portions taires the place of the encasing tube l Il employed in the previous examples.

In the example shown in Figure 8 the invention is applied to the reduction by rolling or the like of individual elements l@ in the form of plates, slabs or the like. As before, these are assembled in the form of a bundle or pack with a separating medium l2 located between adjacent layers. The pack is enclosed in a rectangular actuaba closed in. As before, the separating medium may l be a metal, for example, where the plates lil are of carbon steel, the separating metal may be copper or nickel, or again a pulverulent or like packing such, for example, as powdered (not iiaked) graphite, or metallic oxide may be used.

In any of the foregoing examples the encased bundle may be subjected to hot or cold working. Where the process is applied to the production of ne wires and the main consideration is to minimize any alteration in the cross-sectional shape of the wires, drawing through dies is the preferred method of reduction. At intermediate stages between successive reduction stepsand/or as a iinal operation, annealing or other special heat treatment may be necessary or' desirable, and in this connection it will be appreciated that a process of the type with which the invention is concerned offers substantial practical advantages n that it enables a batch of rods or the like undergoing reduction to be simultaneously subjected to the same heat treatment in the form of a' single unit which can be readily manipulated.

The outer binding or casing for the bundle need not necessarily be a seamless tube. For example, a tubular case with a longitudinal seemed or lapped joint may be used, a separatingy agentsuch, for example, as chromium oxide-being injacent elements may be constituted by an oxide layer of substantial thickness, purposely formed at the surface of theelements with this object in view. Again, an oxide layer may be used in conjunction with the other forms of packing already described.

The processes described herein may be used for the reduction of individual elements lof any desired metal or alloy, and in each case the form and composition of the matrix and outer binding or case will be selected with dueregard to the method which is to be employed for separating the individual elements after the nal reduction, the desirability of minimizing distortion of the original section and other factors which have already been considered. In one example where the process was applied to the production of ne wires of stainless steel containing 18% chromium and 8% nickel, a copper matrix was used and an outer tubular casing of high carbon steel was fine wires.

A further alternative method of removing a high carbon steel outer casing is to bring it into a brittle state by heat-treatment and then to crack it off the bundle.

Thepresent invention has many industrial applications, for example to the manufacture of very For example, starting with nine round section wires of 0.65l mm. in diameter, and of stainless steel having the composition given above, encased in a tube it is readily possible by the present method to produce nal sections with a diameter approaching 0.002 inch, and still of very nearly round section. p

In a further example eighty stainless steel or nichrome (80% Ni, 20% Cr) wires .65 mm. in diamete.` were each encased in separate copper tubes formed by pressing copper strip around the wires and were then packed inside a half inch diameter copper tube. The composite billet thus formed was then reduced by drawing (in another example by rolling) down to a diameter of .17 mm. The copper was then dissolved off leaving the wires which had a diametery of about 0.0004 inch.

Wires of this fine section may be spun into multiple iilament threads, and these may be woven into fabrics. Another application of the invention is to the production of stranded wire, cable or the like. Stranded wire or cable may be produced by reducing a bound or encased bundle of rods or Wires by the methods already described and then imparting a helical twist to the reduced bundle and, where necessary, thermally treating the bundle to set the individual elements or strands and/or to impart any desired physical properties. As before, the encasing tube, binding and matrix are finally removed by chemical, electrolytic or mechanical means. Ii desired, at one or (ach end of the reduced cable or multiple wire, the matrix, where it is of metal such as copper, may be allowed to remain in position so as to form solid end portions which may be vuseful for threading, for instance Where the final product is a iine stranded wire which is to be Woven into a fabric. Where a solid tube is employed for encasing the bundle, it may, if desired7 be recovered as a useful commercial product, i. e. a seamless drawn tube. If this end is in View, the composition of the enclosing tube will be selected with regard to the nature and properties of the material in the recovered tube. When the composite billet has been reduced to the desired size, the tube may be freed from the enclosed elements by cross rolling or any other convenient method.

In the selection of packing material those materials which do not extend uniformly or which tend to bind under pressure (e. g. flake graphite or coachfnlling) are found not to be so suitable as materials which extend uniformly under the pressure of rolling or drawing (e. g. metallic substances, French chalk or chromic oxide) It is within the invention to employ the rcduced bundle in the production of a brush. In this application a portion of the encasing tube is left in position to hold together the individual wires and form a handle for the brush.

l. A process for the production of stranded wire by reduction from elements of comparatively large cross section which comprises the steps of assembling a plurality cf said elements in side-by-side relationship, encasing the assembly of elements, reducing the bundle thus formed as a unit, imparting a permanent helical twist to the reduced bundle and then removing the casing.' l

2. A process for the production of ne wires, strips or the like by reduction from elements of larger cross section comprising the steps of assembling a plurality of said elements in sideby-side relationship, encasing the assembly of elements in a tube of high carbon steel, inserting a packing material within the tube, reducing the bundle thus formed asa unit and then cracking oil the tube. 1

3. A process for the production of ilne Wires by reduction from solid `,elements of larger cross section, which comprises the steps of assembling a plurality of said elements in side-by-side relationship, enclosing the assembly of elements in a tubular casing, inserting a packing material within the casing, reducing the bundle thus formed as a unit and then removing'the casing and packing material and separating the .individual reduced wires.

4. A process for the production of ne'wires by reduction from solid elements of larger cross section, which comprises assembling a plurality of said elements in side-by-side relationship, enclosing the assembly of elements in a tubular casing, providing a matrix for each individual element, reducing the bundle thus formed as a unit and then removing the casing and separating the individual wires.

5. A process for the production of ne wires by reduction from solidelements of larger cross vat least 22% of thevolume within the casing,

reducing the bundle thus formed as a unit and then removing the casing and the packing material and separating the individual wires.

6. A process for the `production of ne wires by reduction from solid elements of larger cross section, which comprises employing elements of cross sections which will fit together without interstices, assembling a plurality of said elements side-by-side in intertting relationship without interstices, the sides of each element acting directly as a matrix for the contiguous sides of adjacent elements, enclosing the assembly of elements in a tubular casing, reducing the. bundle thus formed as a unit and then removing the casing and separating the individual wires.

7. A process for the production of fine wires by reduction from solid elements of larger cross section which comprisesv employing elements whereof the cross section bf' each is thesame and conforms to a regular straight-sided polygon which will interfit without intestices with 'contguo'us elements ,of the same cross section, assembling a plurality of said elementsy in side-byside interiitting relationship, enclosing the assembly of elements in a tubular casing, reducing the bundle thus formed as a unit and then removing the casing and separating the individual wires.

8. A process for the production of fine Wires from solid elements of larger cross section, which comprises the steps of assembling a plurality of said elements in side-by-side relationship, 'eni the inner wall of the casing with a packing material, reducing the bundle thus formed as a unit,

then removing the casing by dissolving with an acid, removing the packing material and sep= arating the individual Wires.

9. A process for the production of une Wires by reduction from solid elements of larger cross section, which comprises the steps of assembling a plurality of said elements vin side-by-side relationship, enclosing the assembly of elements in a tubular casing, running a molten metal packing into the casing to embed the elements, reducing the bundle thus formed as a unit and then removing the casingI and tbe metal packing to separate the individual wires. l0. A process for tbe production oi due wires ci stainless steel by reductiontrorn solid elements of suoli material of larger cross section, which comprises tbe steps ot enclosing veacli element in a separate copper sheath, assembling a plurality of such sheathed elements in side-by-side relationsliip, enclosing tbe assembly in a copper tube, reducing the bundle 'tinus formed as a unit and then removing the casing and tbe slieatiis by dis= solving oi the copper, and separating tlie reduced wires.

il. .l process for tne production ci une wires by reduction from solid elements of larger cross section, which comprises tbe steps of assenibling a plurality ci said elements in side-bymside rela tionship, lielically binding the assembly, enclos ing the bound assembly in a tubular casing, reg ducing the bundle tinus formed as a unit, rernov ing the casing, unvvinding the lielical binding and separating tine reduced tvires.

i2. il process for tlieproduction oi tine 'Wires reductionirorn solid elements of larger cross section, which comprises tbe steps of forming layers oi oxide ot substantial tl'iicliness on the surfaces o tbe elements, wsernbllng a plurality oi said oxidized elements in sidembghside relationsnip, enclosing the assembly ot elements in a tubular casing, reducing tire bundle tlius formed as a unit and then removing tire casing and sep arating tbe individual wires.

i3. An article oi manufacture comprising a aosoaoe exible metal libre having a surface such as formed on metallic strands when elongated in a bundle with other strands with a separating vmatrix and of such small cross-sectional area that it may be spun into multiple-ment threads. v

1i, An article of manufacture comprising a flexible metal nbre of thread-like length having a surface such. as formed on metallic strands when elongated in a bundle with other strands with a separating matrix and or across-sectional area such that the bres may be spun into multiple-diametri; threadscapable of being Woven into exible fabrics.

l5; An article of manufacture comprising a exible metal' fibre of thread-like length having a surface such as formed on metallic strands when elongated in a bundle vvitb other strands with a separating matrix and of a cross-sectional area such that the fibres maybe spun into multiple-lament threads comparable in iieiubility to threads formed from organic fibres and capable of being woven into a iabric.,

i6. An article o manufacture comprising a fabric woven rom stranded multiple-filament threads of metal, the threads being spun from metal fibres having a diameter oi an order ranging from 0.002 incn -to 0.0004 inch and having a surface suoli as formed on metallic strands when elongated in a bundle with other strands with a separating matrix. v

l?. .lin article oi manufacture comprising a lielically twisted cable consisting of a bundle of flexible fibres off small cross-sectional area, all o vlbicli bres are reduced in cross-sectional .in a bundle. f

An article of manufacture comprising a flexible and ductile metal libre oi a diameter of an order ranging from 0.002 inclu to 0.0004 inclu and having a surface sucio. as formed on metallic strands 'when elongated in a bundle with other? strands with a separating matrix.,

SAMUEL JAR/DES