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APPARATUS FOR CONTINUOUS FRICTION-ACTUATED EXTRUSION
Field of the Invention The present invention relates generally to continuous extrusion of metal, and more particularly to a continuous extrusion machine to produce generally continuous lengths of wire strips and other shapes.
Background of the Invention In a conventional continuous extrusion process, metal is continuously drawn by friction through a passage to an abutment that obstructs the passage and forces the metal through a die orifice to form a generally continuous extrusion of metal, typically wire. The passage is formed between an annular groove formed in the surface of a rotatable cylindrical die and an arcuate surface of a stationary die. The die orifice is formed in or near the abutment at the end of the passageway. Continuous extrusion machines are typically used for forming copper or aluminum wire (not necessarily round in cross-section). The present invention relates generally to an improved continuous extrusion machine for extrusion of generally continuous metal shapes from metallic powders, and more particularly for extruding generally continuous shapes from copper powder.
Summary of the Invention
In accordance with a preferred embodiment of the present invention, there is provided a continuous, friction-actuated extrusion apparatus comprised of a cylindrical first member having a circumferential groove formed in its peripheral surface. A stationary second member projects into the groove and defines a passageway between the first member and the second member, the passageway having an entry end and an exit end. Means for rotating the cylindrical first member are provided such that the first member travels in a direction from the entry end to the exit end of the passageway. A metal feeding device feeds metal into the passageway at the entry end.
An abutment member extending across the passageway at the exit end thereof forces the metal powder through at least one die orifice located at the exit end of the passageway. At least one restriction member is located in the passageway between the orifice and the entry end, the restriction member constricting the passage for a portion thereof.
In accordance with another aspect of the present invention there is provided a continuous friction-actuated extrusion apparatus, comprised of a passageway
extending from an entry end to an exit end between an arcuate first member and a second member. The second member is in the form of a wheel having circumferential groove formed in its peripheral surface into which groove the first member projects Means are provided for rotating the wheel in such a direction that those surfaces of the passageway constituted by the groove travel from the entry end towards the exit end Metal feed means for feeding metal into the passageway are provided at the entry end At least one die orifice is located in or adjacent to an abutment member extending across the passageway at the exit end thereof for extrusion of material from the passageway At least one restriction is formed in the passageway between the die orifice and the entry end of the passageway The restriction reduces the average cross-sectional area of the passagew ay by at least 40%
It is an object of the present invention to provide a continuous extrusion machine for continuous, friction actuated extrusion of metal from metal powders Another object of the present invention is to provide a machine as described above for extrusion of copper wire from copper powder.
Another object of the present invention is to provide a machine as described above that reduces internal stresses within the formed wire.
A still further object of the present invention is to provide a machine as described above that provides a pre-extrusion process prior to extrusion at the forming
These and other objects and adv antages w ill become apparent from the following description of a preferred embodiment of the present invention, taken together with the accompanying drawings Brief Description of the Drawings
The invention may take physical form in certain parts and arrangement of parts, a preferred embodiment of which will be described in detail in the specification and illustrated in the accompanying drawings which form a part hereof, and wherein
FIG 1 is a fragmentary view of a conventional continuous extrusion machine showing in cross-section a portion of the wheel, the stationary die and the abutment.
FIG 2 is an enlarged sectional \ lew of a continuous extrusion machine illustrating a preferred embodiment of the present invention;
FIG 3 is an enlarged sectional view of the continuous extrusion machine sho n in FIG 1 schematically illustrating the flow of metal therethrough.
FIG 4 is an enlarged sectional view of the continuous extrusion v iew shown in FIG 2 schematically illustrating the flow of metal therethrough, and FIG 5 is an enlarged sectional view taken along lines 5-5 of FIG 2.
FIG 6 is an enlarged sectional view taken along lines 6-6 of FIG 2. FIG 7 is an enlarged sectional view taken along lines 7-7 of FIG 2. FIG 8 is an enlarged sectional view taken along lines 8-8 of FIG 2, FIG 9 is an enlarged sectional view taken along lines 9-9 of FIG 2. FIG 10 is a side elevational view of lestπction members illustrating alternate shapes
Detailed Description of Preterred Embodiment Referring now to the drawings wherein the showings aie for the purpose of illustrating a preferred embodiment of the invention only and not for the purpose of limiting same. FIG 1 sho s a portion of a conventional continuous extrusion machine 10 Continuous extrusion machine 10 includes a relatively large wheel 12 having an outer cylindrical surface 14 Wheel 12 is rotatable about an axis by a driv e assembly (not shown) In the drawings, wheel 12 is shown being rotatable m a clockwise direction A groove 16 is formed in surface 14 about the periphery of wheel 12 A stationary die assembly 22 is disposed adjacent to wheel 12 Die assembly
22 is generally comprised of a shoe 24. an abutment 26 and a die 28 In the embodiment shown shoe 24 is comprised of a plurality ot segments designated 24A, 24B. 24C and 24D Λ portion of shoe 24 is disposed within groove 16 as best- illustrated in FIGS 5-9 A. passageway 32 is defined between wheel 12 and shoe 24 Passageway 32 is defined by a surface 16a of groove 16 and by a surface 25 defined by shoe 24 In conv entional continuous extrusion machines, shoe 24 is shaped such that the cross-sectional area of passageway 32 becomes gradually smaller in the direction of rotation of wheel 12 The end of passageway 32 with the larger cross- sectional opening defines an entry end, designated 34 in the drawings, for receiv ing metal as shall hereinafter be described An exit end 36 of passageway 32 is defined by abutment 26 butment 26 is dimensioned to project into groov e 16 and to substantially match the cross-section thereof At entry end 34 of passageway 32 a chute 42 is disposed to intersect groove 16 Chute 42 is connected to a metal feed
assembly (not shown) to provide metal into groove 16, as is conventionally known in the conforming art.
Die 28 is disposed at exit end 36 of passageway 32. Die 28 includes a die orifice 44 extending therethrough Die orifice 44 defines the cross-sectional shape of the generally continuous strip or wire to be formed by continuous extrusion machine 10. In the embodiment shown, die orifice 44 is orientated radially to wheel 12 It is of course appreciated that die orifice 44 may alternately be formed through abutment 26 Continuous extrusion machine 10 as described heretofore is typical of continuous extrusion machines known heretofore. Referring now to FIG 2. a continuous extrusion machine designated 10' illustrating a preferred embodiment of the present invention is shown Continuous extrusion machine 10' is like continuous extrusion machine 10 in all respects ith the exception that a restriction member 50 is disposed within passageway 32 Restriction member 50 is located between die orifice 44 and entry end 34 of passageway 32. Restriction member 50 is provided to significantly constrict, i.e.. reduce, the cross- sectional area of passageway 32 for a specific length designated "L." In accordance with the present invention, restriction member 50 preferably reduces the cross- sectional area of passageway 32 immediately preceding restriction member 50 by at least 30%), and more preferably by about 40%o to about 60%>, most preferably by about 50%o Length L is preferably about 15mm to about 20mm and more preferably about 17mm. Restriction number 50 is preferably located near die orifice 44 and more preferably immediately preceding die orifice 44 Restriction member 50 defines a chamber 52 that is bounded by heel 12, abutment 26, die 28 and restriction member 50 Referring now to FIGS 3 and 4. the operation of continuous extrusion apparatus 10'. and more specifically, restriction member 50, shall be described. The invention shall be described by contrasting the operation of continuous extrusion machine 10' to the operation of a conventional continuous extrusion machine 10, as shown in FIG. 1 In continuous extrusion machine 10, metal powder, designated Mp is fed into groove 16 via chute 42 as wheel 12 rotates past chute 42. In the drawings, metal powder Mp is schematically illustrated by "flecks" or "peppering" in chute 42 and passage 32. Metal powder Mp is dragged by friction between moving surface 16a
of groove 16 and surface 25 of shoe 24 toward abutment 26 As the opening of passageway 32 gradually decreases the cross-section, metal powder Mp is compressed as it is dragged toward abutment 26. The particulate metal powder Mp is drawn through passageway 32 under a continuous metal drag force until it reaches the end of passageway 32 and is forced through die orifice 44 to form a generally continuous wire. As metal powder Mp is dragged along passageway 32. it begins to change from a powder form to a more solid-like mass of metal. In the drawings, the more solid-like mass of metal is schematically illustrated in the drawing using conventional cross latching and is designated Ms Though metal powder Mp and melted solid Ms do not melt, it is believed that the flow of metal can be modeled as a fluid using well-established principles of fluid mechanics. In this respect, it is believed that the metal particulate Mp and semi-solid metal Ms in contact with, and nearest to, the surface 16a of groove 16 has a higher speed through passageway 32 than does the metal powder in contact with stationary surface 25 of shoe 24 As a result, a non-uniform laminar flow is believed to exist near die orifice 44. as illustrated in FIG. 3, vvheie flow lines 66 schematically show how the metal near the surface of wheel 12 is forced into abutment 26 and then directed toward die orifice 24 while the metal near stationary surface 25 of shoe 24 moves more slowly toward die orifice 44 It is believed at the point where fπctional bonding of the metal powder has begun the faster and slower moving metal particulate create internal stresses within the extruded wire, particularly for certain cross-sectional shapes such as rectangular w ire These inherent stresses produce a weak stress plane along the axis of the wire
Referring now to FIG. 4, a metallic flow pattern for continuous extrusion machine 10' is schematically shown. As illustrated in FIG 4, the cross-sectional area of passageway 32 is significantly reduced by restriction member 50 forcing the metal through a smaller passage defined between the surface of restriction member 50 and surface 16a of groove 16 As a result, a number of events are believed to occur First, metal powder Mp is compacted and becomes densei as it is forced through the smaller cross-sectional opening defined by restriction member 50. Second, the velocity of the metal increases, and more importantly the velocity differential between the metal is reduced in that the space between moving surface 16a of groove 16 and the stationary surface of restriction member 50 are reduced. In addition, the velocity of the metal is
increased by the very fact that the equation of continuity requires a higher velocity for the material to pass through the reduced cross-sectional area defined by restriction member 50 Third, the increase in velocity produces a more uniform laminar flow through the constricted portion of passageway 32. As a result, it is believed that a preliminary extrusion takes place as the metal is forced through the reduced passageway defined between restriction member 50 and surface 16a of groove 16 It is further believed that the metal begins to fuse together to form a somewhat continuous mass that is diverted and directed by abutment 26 through die orifice 44
As schematically illustrated in FIG 4, in corners or pockets, such as these designated 62a, 62b, 62c and 62d, the metal w ill naturally build up and become stationary. In such areas a natural contour will develop to direct the metal past restriction member 50 and toward and through die orifice 44
FIGS. 5 through 9 schematically illustrate the transition of metal powder MP to a generally continuous wire W FIG. 5 shows metal powder Mp disposed in passageway 32. As the opening of passageway decreases in the direction of rotation of wheel 12. metal powder Mp begins to fuse together under the pressure and fπctional heat generated by the metal powder being dragged down passageway 32. FIG 6 show s a cross-section through passageway 32 about midway between entry end 34 and exit end 36. As schematically illustrated in FIG 6, the metal has begun to solidify into an extrudable solid mass (as indicated by "crosshatching") near the surface of groove 16 of wheel 14 and generally remain a powder (as indicated by "peppering") near the stationary surface of shoe segment 24A. FIGS 7 and 8. respectively, show metal M immediately preceding and adjacent restriction member 50 At these locations, it is believed that metal M is essentially a solid, but extrudable, mass Forcing the metal past restriction member 50 significantly compresses the metal, and as suggested above temporarily increases the speed of the metal.
The compressed metal is forced into cavity 52 that precedes die orifice 44 It is believed that in this area the metal is a solid, but extrudable mass, that is extruded through die orifice 44 into wire W by the pressuie created by wheel 12, as illustrated by FIG. 9. It is believed that the metal forced past restriction member 50 has a more uniform temperature, velocity and compaction as it enters cavity 52 immediately preceding die orifice 44. It is also believed that restriction member 50 creates a
preliminary extrusion process that compacts the metal prior to its ultimate extrusion into w ire W through die orifice 44
The foregoing explanation is based upon a belief as to what occurs as a result of the presence of restriction member 50 in passageway 32. Regardless of the actual events caused by restriction member 50, the use of such member results in an enhancement in the quality of wire formed.
The invention shall now be further described together with the following example wherein a w ire formed by a conv entional continuous extrusion machine 10 without restriction members 50 is contrasted to a wire form by the same continuous extrusion machine hav ing restriction member 50 disposed in passageway 32
EXAMPLE A test is conducted to contrast w ire formed by a conv entional continuous extrusion machine 10 with wire formed in the same continuous extrusion machine but including restriction member 50 In the tests, a BWE continuous extrusion machine was used under the same operating conditions, using a die 28 having the same die orifice 44. Restriction member 50 is a rectangular block that reduces the cross- sectional area of passageway 32 by about 50%. In both tests, a 0.197 by 0 079 rectangular copper ire was formed from copper powder having a D^o particle size of about 200 Mesh (Tyler) Table 1 show s the operating characteristics of the continuous extrusion machine when used w ith and without restrictive member 50
TABLE 1
Table 2 show s the physical properties of wire formed using the continuous extrusion machine 10 without restriction member 50 and wire formed by the continuous extrusion machine 10' using restriction member 50
TABLE 2
PHYSICAL CHARACTERISTICS OF WIRE PRODUCT
Continuous Extrusion Continuous Extrusion
Machine vv/o Restriction Machine with Restriction
Member Member
Ultimate Tensile Strength 34.1 ksi 34 4 ksi
2% Yield Strength 24.1 ksi 15 3 ksi
Total % Elongation 28 5 % 48 4 %
:= of Surface Defects 624 eddy current count 125 eddy current count
The results show significant improvements in the quality and properties of wire formed with restriction member 50 m passagew ay 32 as compared to w ire formed without a restriction in passageway 32 Specifically. Table 2 shows only a slight difference in tensile strength between the tw o w ires, but show s a dramatic difference in both the yield strength and elongation properties between the two wires The lower yield strength and higher elongation are both desirable characteristics in wire of the type disclosed that is typically used in motor pole w indings More importantly, however, wire formed with modified machine 10' showed significantly less surface defects as measured by a conventional eddy current technique.
The present invention thus provides a method of improving the properties of wire formed from metal particulate, and m particular copper powder by inserting a restriction member 50 ithin a passageway of a conventional continuous extrusion machine. It is believed that restriction member 50 produces a first extrusion process within passageway 32 that prov ides a preliminary compression and bonding of the copper particulate On information and belief, this preliminary extrusion produces a generally more compact stream of copper that is directed tow ard die orifice 44 to provide a continuous w ire w ith more desirable properties The foregoing description discloses a restriction member 50 of a specific rectangular shape. It is believed that other shapes may likewise produce the desired end results For example, it was found that using the rectangular restriction member 50 produced a dead zone of built-up or packed copper at the leading end of restriction member 50. In other words, the copper powder built a corner or fillet, and produced a region of stagnant stationary copper that formed a ramp that generallv directed the metallic powder into the reduced passageway between restriction member 50 and groove 16 It is therefore believed that restriction members having a taper or
chamfered leading end may provide more uniform laminar flow of the metal paniculate into the restricted metal passageway. FIGS. 10 through 15 thus show alternate configurations for restriction member 50. Specifically FIGS. 10 and 1 1 show restriction members 50 that have a contoured leading edge to guide metal M into the restriction. FIGS 12 and 13 show restriction members 50 with chamfered and tapered leading edges FIGS 14 and 15 show still other embodiments for forming a restriction in passageway 32.
The foregoing description is a specific embodiment of the present invention. It should be appreciated that this embodiment is described for purposes of illustration onh . and that numerous alterations and modifications may be practiced by those skilled in the art without departing from the spirit and scope of the invention It is intended that all such modifications and alterations be included insofar as they come within the scope of the invention as claimed or the equivalents thereof