US3845805A

US3845805A - Liquid quenching of free jet spun metal filaments

Info

Publication number: US3845805A
Application number: US00306472A
Authority: US
Inventors: S Kavesh
Original assignee: Allied Chemical Corp
Current assignee: Allied Corp
Priority date: 1972-11-14
Filing date: 1972-11-14
Publication date: 1974-11-05
Anticipated expiration: 1991-11-05
Also published as: JPS5926685B2; FR2225239B1; IT996955B; FR2225239A1; JPS49135820A; CA1012328A; GB1458017A; DE2355524A1

Abstract

A process is provided whereby filaments of metals may be formed by rapid solidification of a molten jet in a fluid medium. Filaments of metastable alloys such as amorphous metals and filaments of fine grained structure having novel orientation may be obtained.

Description

United States. Patent 1 Kavesh 1 Nov. 5, 1974 [5 1 LIQUID QUENCHING or FREE JEIMSPUNB METAL FILAMENTS [75] Inventor: Sheldon Kavesh,'Whippany, NJ.

[73] Assignee: Allied Chemical Corporation, New

1 York, NY.

22 Filed: Nov. 14,1972

21 Appl. No.: 306,472

[52] US. Cl. 164/89, 164/283 S, 264/180, 425/71 [51] Int. Cl B22d 11/12 [581 Field of Search 164/81, 82, 89, 283 5; 264/176 F, 180; 425/71 156] References Cited UNITED STATES PATENTS 2,879,566 3/1959 Pond 164/81 X 2,907,082 10/1959 Pond 164/89 X 3,347,959 10/1967 Engelke et al.. 164/89 X 3,430,680 3/1969 Leghorn 164/81 3,602,291 8/1971 Pond 164/283 S Primary Examiner-R. Spencer Annear Attorney, Agent, or FirmArthur .1. Plantamura [57] ABSTRACT A process is provided whereby filaments of metals may be formed by rapid solidification of a molten jet in a fluid medium. Filaments of metastable alloys such as amorphous metals and filaments of fine grained structure having novel orientation may be obtained.

11 Claims, 16 Drawing Figures -OUENCH FLUID PATENTEDunv 5mm 845805 -CD I STANDPIPE 'QUENCH FLUID PATENTEDHUY 519m 7 4 sum 20% "845505 BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to the free casting of metals and to the filaments which are thereby produced.

eser pt oe. e fe t A.

The preparation of metal wires by drawing through a die is an old art which is known to have been practiced by hand at least as early as 1000 AD. Metal filaments are still principally produced by pulling a large diameter rod through a succession of tapered dies, each one progressively smaller than the one before. In modern practice, the die drawing process has been mechanized, made continuous and automated; yet, the process remains essentially unchanged as do a number of associated problems and limitations.

Research in recent years has been directed toward the development of methods of filament formation which avoid the restrictions of die drawing. One of the approaches under investigation involves free casting or direct melt spinning and concerns the formation of a free jet of molten fluid and the transformation of the jet to the solid state. This procedure may be employed to form filaments of polymeric materials and glasses, i.e. materials having very high viscosities and low surface tension in the liquid state. In contrast, however, metals have relatively inviscid melts of high surface free energy. A cylindrical jet of such a material is inherently unstable. Its surface becomes increasingly perturbed as it issues from the nozzle until at some distance the jet breaks up into droplets. Accordingly, a process, if it is to be capable of producing continuous filaments of metals, must provide a favorable balance between the kinetics of jet solidification and of jet breakup.

Although several processes for the melt spinning of metal fibers have been proposed to effect a stabilization of the molten jet as a means of achieving the required balance, no process has been significantly successful. In one process, the jet is extruded into a gaseous atmosphere capable of chemical reaction with one or more of the components of the jet. Stabilization occurs by formation of a solid sheath or skin on the liquid jet. Alternatively, electrostatic charges have been used to stabilize the jet.

Several techniques have also been proposed for hastening the solidification of the jet. For example, Pond in US. Pat. No. 3,602,291 describes cooling of the molten jet by a mist of a vaporizing liquid dispersed in a gas. Schile (US. Pat. No. 3,543,831) employs cooling by a gas-solid dispersion. Engelke et al. (U.S. Pat. No. 3,347,959) discloses immersing the 'iaei'zre from which the molten jet issued in a liquid mold stream" maintained at a slightly lower temperature than the melt. However, the solidification rate in each of these processes remains fairly slow and chemical or electrostatic stabilization of the jet is still required. Additionally, when a nozzle is immersed in the cooling medium, serious practical difficulties are present, e.g., unsuitable quenching and corrosion problems.

The need for chemical stabilization of a molten jet imposes several hardships upon a spinning process; among these are the following:

l. The addition of a reactive element to a pure metal or metal alloy may have a detrimental effect on mechanical, electrical or other of its physical properties.

2. Precise control of melt and/or atmospheric compositions is required, lest the attendant chemical reaction causes plugging of the spinning orifice on the other hand or inadequate stabilization of the jet on the other.

3. The choice of crucible and orifice material which may satisfactorily resist erosion and chemical attack is limited.

4. The reactive gaseous atmosphere may be noxious, inflammable, explosive, corrosive or expensive.

It is well known that there are a number of disadvantages in working with high electrical potentials to effect electrostatic jet stabilization.

SUMMARY OF THE INVENTION An object of this invention is to provide a method and apparatus for the production of filaments from their melts which are applicable to materials exhibiting sharp melting behavior and broad melting ranges, i.e., to pure metals and to alloys.

Another object of the invention is to provide a method and apparatus for the production of filaments of this kind from their melts wherein there is no dependency upon special techniques of jet stabilization.

A further object of the invention is to provide a method and apparatus for the production of filaments of metastable alloys, such as amorphous metals and of non-ductile alloys not readily formed into filaments by conventional means.

Still a further object of the invention resides in the preparation of filaments having a fine grained structure of novel orientation.

Other objects and advantages of this invention will be apparent from the following description and drawings.

The melt spinning process of the invention involves the formation of a free jet of the molten material in a gaseous or evacuated environment, traversal of the free jet through an interface into a fluid medium, the fluid medium flowing cocurrent with the jet and at essentially the same velocity as the jet and the rapid solidification of the jet in filamentary form. A free jet is defined as a stream of fluid unconfined by solid boundaries. The fluid medium may be a pure liquid, a solution, an emulsion, or a solid-liquid dispersion. The fluid medium may react with the molten jet to form a stabilizing surface skin or it may be chemically unreactive with the molten jet. The fluid medium and its temperature are selected to suppress formation of a film boiling regime along the jet surface and to enhance the formation of a high heat flux regime, i.e., a nucleate surface boiling regime or a forced convection heat transfer re-, gime in which the coefficient of heat transmission is at least 0.4 cal/sq. cm.-C sec.

The terms film boiling and nucleate boiling are well known in the art. The term regime connotes the condition or pattern, usually dynamic, which obtains at a specified point or stage in the process. The quenching of metals in liquids under conventional conditions is disclosed, for example, by Hollomon and .laffe in Ferrous Metallurgical Design, pg. 6265, John Wiley and Sons, New York, 1947. Normally, when the metal is first immersed in the medium, the adjacent liquid is rapidly heated to the boiling point and transformed into vapor. A vapor film is set up around the metal which 3 retards the further transport of heat. A film boiling regime is said to exist.

As the surface temperature falls, the vapor barrier loses integrity and liquid comes into direct contact with the metal. Vapor bubbles form at active nuclei on the metal surface and are quickly detached. Heat transfer is very rapid in this nucleate boiling regime with heat transfer coefficient approximately 30 fold greater than for film boiling. Finally, when the temperature of the liquid at the interface is less than the boiling point, boiling ceases and the metal continues to be cooled rapidly by convection.

In contrast, under the conditions which are described in conjunction with the invention, jets of molten materials entering liquid media demonstrate nucleate surface boiling heat transfer or forced convection heat transfer with total suppression of film boiling along the critical entry region. As a consequence, cooling and solidifieation of the jets have been greatly enhanced. This result coupled with unexpected stability of molten jets within fluid media has enabled the transformation of the jets into solid filaments in the brief interval before jet disruption. The very rapid heat transfer permits the preparation of substantially improved continuous round filaments of amorphous metals as well as the preparation of novel crystalline filaments of fine grained equiaxed or oriented structure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 illustrates diagrammatically an apparatus which may be utilized in making metal filaments according to the invention.

FIG. 2 is a detail of one embodiment of a quenching means wherein a baffle is used to suppress formation of a vortex.

FIG. 3 and FIG. 3a illustrate details of an alternate arrangement for preventing vortex formation during quenching.

FIG. 4 illustrates still another means to avoid vortex formation during the quenching step.

FIG. 5 is a perspective illustration of an alternate quenching and filament support arrangement for the extruded jet.

FIG. 6 is a photomicrograph (magnification 6X) of a melt-spun filament made according to the invention and characterized by a smooth surface.

FIG. 7 is a photomicrograph (magnification 12X) of a melt-spun filament according to the invention characterized by a corrugate-like surface texture.

FIG. 8 is a photomicrograph (magnification 6X) of a melt-spun filament made by the invention and having a pearl necklace"-like surface texture, i.e., a surface texture having alternating linear and spheriodal segments.

FIG. 9 is a photomicrograph (magnification 12X) of a melt-spun filament prepared according to the invention characterized by a serrated or saw-tooth structure.

FIG. 10 is a photomicrograph (magnification 12X) of a melt-spun filament prepared according to the invention having a kinked texture.

FIG. 11 is a photomicrograph (magnification 12X) of a melt-spun filament prepared according to the invention having a corkscrew-like configuration.

FIG. 12 is a photomicrograph (magnification l76X) of a cross section of a cast commercial gray iron bar.

FIG. 13 is a photomicrograph (magnification I76X) of a cross section of a filament melt spun according to the invention from the composition illustrated in FIG. 12.

FIG. 14 is a photomicrograph (magnification 145X) of a cross section of melt spun zinc wire prepared according to the invention.

FIG. 15 is a comparative photomicrograph (magnification 38OX) ofa zinc wire made by conventional prior art wire drawing techniques.

DESCRIPTION OF THE PREFERRED EMBODIMENTS The process and a laboratory spinning apparatus are illustrated in the accompanying FIGS. 1-4. A metallic material to be melt spun in charged to a vessel 21 of suitable heat tolerant material for the particular metal to be processed, e.g., an insulated ceramic crucible fabricated, for example, from quartz or zirconia insulated with zirconia felt 22. The crucible has one or more bottom openings or spinning orifices, one of which is shown at 23 and whose diameters are the order of size of the desired diameter of the filaments, e.g. 0002-0060 cm. The crucible 21 lies within a chamber defined by a quartz cylinder 24, an insulated copper plate at the top 25, and a ceramic plate 26 such as boron nitride at the bottom. The chamber assembly is suitably held together such as by external tie rods 27.

A quartz window 28 may be conveniently inserted in the top cover plate to permit measurement of charge temperatures such as by an optical pyrometer 29 which is provided with a suitable readout 29a. An inert gas pressure source, e.g., helium, is connected to the top cover plate 25. A pressure tight seal is effected between the crucible 21 and the bottom plate 26 by a suitable commercial ceramic casting compound. For example, when using a quartz crucible and a boron nitride plate, a commercial compound Ceramacast-505, available from Aremco Products Inc., Briarcliffe Manor, New York, yields a tight seal. Energy to melt the metal charge is provided by a power source such as a 450 KHZ induction power supply connected to a coil 31 concentrically wound about the melting chamber 24. For example, a quartz crucible having a wall thickness of at least 1 mm may be used with metals whose melting points are less than about 1300 C. The spinning orifices 23 may comprise holes drilled through the bottom wall of the crucible using diamond tools or laser methods although other orifice arrangements or dies may be employed. Since tapered nozzles enhance jet stability, it is preferred that the holes be tapered.

By way of a specific illustration, a zirconia crucible ofabout one-fourth wall thickness is preferred for spinning metals whose melting points are 1300-1700 C. The crucible 31, when formed of zirconia, is drilled and reamed to accept a separately fabricated zirconia spinnerette (not shown) containing the spinning orifices. Mating of the spinnerette to the spinning crucible is accomplished by means of a zirconia based ceramic cement such as Ultratemp 516, available from Aremco Products, Inc., Briarcliffe Manor, New York.

Referring again to FIG. 1, the melting chamber is suspended immediately above a reservoir 47 containing the fluid quench medium 40. The level of the fluid medium 40 is controlled as close as possible but without contacting the bottom plate 26 of the melting chamber 24. Generally, this distance is of the order of about 0.2 cm.

The space 41 between the spinning nozzle and the surface of the fluid quench medium confined by walls 38 may be evacuated or it may be filled with an inert gas or a gas which enhances the formation ofa stabilizing skin or the molten filament jet. This inert or gas filled zone 41 isolates the melting and jet formation zones from the quenching zone and permits the establishment of wide temperature differentials which would not be practical if the chamber 24 and the fluid 40 were in contact. A quartz cylinder 38 cemented on one end to the bottom 26 of the melting chamber and on the other end immersed in the fluid quench medium 40 provides the chamber 41 into which the inert gaseous atmospheres from a source 45a through line 45 may be admitted. Alternatively, the space 41 may be evacuated. Within the fluid reservoir 47, disposed vertically below the spinning orifices 23 is a vertical standpipe 33. The fluid quench medium 40 enters the reservoir 47 at one end 48, passes horizontally through a calming screen 34, flows vertically down through the standpipe 33 into a catch basin 35 and finally by means of a pump 39 is passed through a heat exchange, in this case a refrigeration unit 37, and is returned via line 46 to the reservoir '47. Fine jets of the quench fluid 44 are sprayed from the sparger ring 30 into the mouth of the standpipe 33. It is essential that the quench medium 40 and its temperature be controlled so as to suppress formation of a film boiling regime along the jet interface. Preferably, the quench medium and its temperature are selected to create a nucleate surface boiling regime along the region of entry of the jet into the quench fluid.

The selection of the quench medium and its temperature must be made in relation to the thermal capacity of molten jet. The thermal capacity of the jet increases in direct proportion to its temperature, specific heat, latent heat of fusion and its cross-sectional area. Suppression of film boiling in the thin boundary layer of quench fluid surrounding the molten jet can be accomplished by causing the thermal capacity of the jet to become depleted in raising the quench fluid boundary layer to the boiling point. Thus, the greater the thermal capacity of the .molten jet, the colder must be the quench fluid and/or the higher its specific heat, density, heat of vaporization and thermal conductivity.

Other desirable qualities of the fluid quench medium are low viscosity to minimize disruption of the molten jet, nonflammability, non-toxicity, optical clarity and low cost. In accordance with the invention, I have discovered that water at Ol0C. is a satisfactory medium for spinning materials whose melting points are less than about 700 C., e.g. aluminum, zinc, lead, tin, bismuth, cadmium, etc. For materials whose melting points are above 700 C. to about [000 C., however, a refrigerated (-C.) 23 weight percent aqueous sodium chloride solution is satisfactory. For spinning materials whose melting points are in the range l000-l500 C. or l500-l700 C., a fluid medium of 21.6 weight percent aqueous magnesium chloride at 33 C. or 5] weight percent aqueous zinc chloride at -62 C., respectively, is preferred. It will be understood that the foregoing quench fluids merely represent typical fluids which may be employed in the practice of the present invention and that a variety of alternative quench fluids compatible with the particular jet composition and its temperature may be employed. The quench fluid into which the molten jet is injected is arranged so as to flow cocurrent with the jet and is everywhere during the main quench period, i.c.. during the time interval that the molten jet is in its transition to a solid phase, at the same velocity as the jet. In the present apparatus, depicted in the drawing, the molten jet and the quench fluid flow together at substantially the same velocity in the standpipe. Above the standpipe, the motion of the quench fluid is in the same direction as the jet but the fluid velocity accelerates from zero at the air-fluid interface to a maximum in the standpipe.

The top of the standpipe is placed as close as practicable to the surface of the quench fluid; typically, it may be within 2 cm of the fluid surface. Vortex forma tion above and within the standpipe is substantially minimized by positioning a vortex baffle near the standpipe. Illustrated in FIG. 2 is a simple asymmetric vortex baffle consisting of a bar of rectangular cross section 50 placed to one side ofthe standpipe and extending to the surface of the fluid 40. In FIG. 3, a vortex baffle comprising an annular sparger ring 30 placed above the standpipe 33 and extending to the surface of the fluid 40 is shown to minimize the vortex formation and control the fluid velocity flow indicated by arrows 52 in standpipe 33. Fine jets of the quench fluid are sprayed from the sparger ring 30 into the mouth of the standpipe 33. The velocity of the fluid medium in the standpipe is determined by the diameter of the standpipe 33, the height of fluid surface above the standpipe, and the velocity and volume of flow sprayed into the standpipe from the sparger ring 30 which is fed from line 51 (also shown in FIG. I); for example, a typical fluid velocity using a 1.4 cm I.D. standpipe of 40 cm length, an aqueous quench medium of 1.0 cps viscosity, 1.0 g/cc density, a fluid level 2 cm above the standpipe, and zero spray velocity is 200 cm/sec.

As illustrated in FIG. 4, another alternative comprising one or two rotating cylinders (two being shown in FIG. 4) may be placed at the mouth of the standpipe. The presence and rotation of the cylinder 53 and 54 substantially curtails vortex formation and increases the uniformity of the fluid velocity field above the standpipe.

In still a further embodiment of the invention, as shown in FIG. 5, the motion of the quench fluid cocurrent with the molten jet 58 may be motivated by overflowing a weir 56'onto an inclined plane 57. The melting chamber shown in phantom is mounted directly above the inclined plane 57. The solidified jet 59 is collected in a suitable catch basin 60 containing a cooling fluid which is circulated at 61 and returned via pump 62 and line 63 to the reservoir 64. It will be apparent that a suitable arrangement for continuous winding of the filaments passing into the catch basin 60 may be made.

The operation of the melt spinning process is facile and direct. As shown by reference to FIG. 1, the level of the quench fluid 40 in the reservoir 47 and the fluid velocity in the standpipe 33 are adjusted to desired levels. The metal material is charged to the melting receptacle 21 which is substantially sealed off or isolated so that the charge may be preferably melted in an inert atmosphere and at substantially atmospheric pressure. When the metal temperature is approximately 50-l00 C. above the melting point, the pressure of the inert gas in the melting chamber is raised to l-20 psig or until a molten jet issues from the spinning orifice at the desired velocity. The molten jet is ejected down into the space 41 and thereafter contacts quench medium 40 upon entering the standpipe 33 where it is solidified as it moves cocurrently with the fluid moving in the standpipe. Adjustment of spinning conditions to suit the form of the solidified material desired may be effected as noted in conjunction with FIGS. 6-11 of the drawing. Where sinuous filaments are formed, it is an indication that the jet velocity exceeds the fluid velocity in the standpipe. If discontinuous filaments with tapered ends are formed, it is an indication that jet velocity is substantially less than the fluid velocity in the standpipe. If the filaments show axisymmetrical nodes, melt temperature may be reduced to produce smooth continuous filaments. Alternatively, the temperature and pressure may be adjusted to produce filaments of another desired surface texture or length. Some of the filament textures and/or shapes which can be produced by adjustment of the melt temperature and the relative velocity of the molten jet and quench medium are illustrated in FIGS. 6-11 where FIG. 6 illustrates a smooth filament; FIG. 7 a corrugated configuration; FIG. 8 an intermitten globular shape; FIG. 9 a serrated shape; FIG. 10 has a kinked form and FIG. 11 a spiral or corkscrew configuration. I

Some of the factors relating to the control of the process to obtain the desired shape or alternatively to avoid formation of undesired shapes are as follows. The smooth filament of FIG. 6, for example, is prepared by matching the fluid velocity in the standpipe to the velocity of the molten jet as described above. The corrugated filament of FIG. 7 may result when the fluid velocity in the standpipe is slower, i.e., about 10 percent less than the velocity of the jet. The pearl necklace" appearance of the filament of FIG. 8 may be obtained when the molten jet is superheated, e.g. about 250 C. above its melting point, while the serrated filaments of FIG. 9 may be obtained at conditions otherwise yielding smooth filament but by permitting a vortex to form in the standpipe. This may result even though the jet velocity and the average linear velocity in the standpipe were closely matched. The kinked filaments of FIG. 10 are produced when a fluid velocity in the standpipe is substantially, i.e., about 40 percent, less than the jet velocity. The corkscrew-like resulting filament of FIG. 11 results from the same conditions as the kinked filaments of FIG. 10 except that a vortex was permitted to form in the standpiepe 33.

The invention is further illustrated by consideration of the examples which follow. The first two examples demonstrate that the filament forming process of the present invention is based upon achieving high heat flux cooling and that it is independent of special techniques ofjet stabilization such as oxide film formation.

EXAMPLE I An 8 mm quartz tube whose end was drawn out into a fine tip of 0.025 cm ID. was charged with silver metal of 99.999 percent purity. The quartz tube was placed within an induction heating coil and connected to a helium source. The silver was melted under a helium atmosphere and discharged at l000 C, 10 psig from the quartz tube into the laboratory atmosphere. The velocity of the silver jet determined from the diameter of the jet and the weight of metal collected in a timed period was approximately 250 cm/sec.

A photograph of the molten jet was taken using a 8 microsecond General Radio flash source. The photograph showed the jet became disrupted into discrete droplets at a distance of 0.5 cm from the nozzle or in a time of flight of 2 milliseconds.

The rapid disruption of the jet into droplets was expected since silver is unreactive with oxygen, nitrogen, water vapor and other normal components of the atmosphere and is incapable of forming stabilizing skins with these substances.

EXAMPLE 2 The quartz tube of Example 1 was again charged with silver of 99.999 percent purity. The quartz tube was mounted over the quench fluid reservoir in the same position but in place of the melting chamber illustrated in FIG. 1. The tip of the quartz tube was 0.2 cm above the surface of a 23 percent sodium chloride quench fluid maintained at 20 C. The top of the standpipe was 2 cm below the surface of the quench fluid. Fluid velocity in the standpipe was 2l0 cm/sec.

The silver was melted in a helium atmosphere and the melt extruded from the quartz tube at I00O C.. 10 psig. .let velocity was approximately 250 cm/sec. The molten silver jet traversed the air gap, entered the quench fluid and was solidified in the form of filaments of 0.025 cm average diameter. High speed macrophotographs of the silver jet entering the quench bath showed nucleate surface boiling and forced convection cooling but not film boiling along the jet.

A lower bound to the coefficient of heat transmission between the jet and the quench fluid may be calculated from the condition that the surface of the jet is solidified before 2 milliseconds have elapsed. The heat transfer coefficient so calculated is at least 0.4l cal/sq.- cmCsec. The corresponding quench rate based on the average temperature of the jet is at least 2 X l0 C/sec. Both the heat transfer coefficient and the quench rate are at least an order of magnitude greater than could be obtained with gaseous cooling.

. Examples 3-5 illustrate the novel continuous filament structures obtainable as a result of the rapid solidification intrinsic to the present invention.

EXAMPLE 3 The apparatus depicted in FIG. 1 was charged with a bar of grey iron containing 3.4 weight percent carbon, 2.2 weight percent silicon, 0.6 weight percent maganese, 0.2 weight percent phosphorus and 0.01 percent sulphur. The alloy was melted in a helium atmosphere at I200 C. and extruded through an orifice of 0.025 cm diameter at 2l5 cm/sec. The molten jet was quenched in refrigerated 23 weight percent sodium chloride brine at 20 C. Brine velocity in the standpipe was 2l5 cm/sec. Filaments of 0.030 cm diameter were thereby prepared.

FIG. 12 is a polished and etched section of the original grey iron bar magnified I76 fold. FIG. 13 is an axial cross section of the melt spun filament prepared as described and shown at the same magnification.

The as-received bar shows large flakes and granules of graphite typical of grey cast iron. However, the filaments melt spun from the above were of a fine grained equiaxed dendritic structure novel for grey iron. Dendrite spacing was 2-microns.

Various mechanical and chemical properites of metals such as strength, ductility and resistance to corrosive agents depend significantly on the scales of internal structures or dendrites. It is desirable that the spacing between dendrites be minimal. In typical macroscale castings, dendrite spacings are commonly IQO-JQQOmiatms. While Dun e ln U v, o- 3,658,979 disclose dendrite spacings of 5-25 microns in continuous metal filaments, dendrite spacings obtained with the present invention are of the order of 1-2 microns and represent a significant improvement.

EXAMPLE 4 The apparatus depicted in FIG. 1 was charged with an ingot of an alloy composed of 38 at. percent iron, 39 at. percent nickel, 14at. percent phosphorus, 6 at. percent boron and 3 at. percent aluminum. The alloy was melted in a helium atmosphere at 1050C. and extruded through an orifice of 0.008 inch'diameter at approximately 200 cm/sec. The molten jet was quenched in refrigerated 21.6 percent magnesium chloride brine at 30 C. Brine velocity in the standpipe was 195 cm/sec. Continuous filaments of 0.006 inch diameter were thereby prepared. The filaments were examined for crystallinity by x-ray diffraction using MoKa radiation. Only a broad diffraction peak, characteristic of the amorphous state, was observed. Differential scanning calorimetry showed a crystallization temperature of 424 C. The as-spun filaments were non-crystalline.

EXAMPLE. r r

A flanged carbon crucible was charged with electrolytic zinc of 99.99 percent purity and mounted over the quench fluid reservoir in the same position but in place of the melting chamber of FIG. 1. The zinc was melted in a helium atmosphere and extruded through a 0.025 cm orifice at 430 C. and 4 psig. Water at 11 C. was employed as the quench medium. Water velocity in the standpipe W.% .l. ..lSI!? SF Axial cross sections of the melt spun 99.99 percent zinc wire and a commercial die drawn zinc wire of the same purity are shown in FIGS. 14 and 15. Tensile properties of these materials were as follows:

Ultimate Tensile Diam., Strength "/1 in. PS1 Elong.

Melt Spun Zinc Wire 0.0068 10.770 3.4 Die Drawn Zinc Wire 7 0.0029 7,265 3.8

Zinc is an illustrative exampleofmetal whose crystal structure is hexagonal close packed (H.C.P.). Other examples of H.C.P. metals include beryllium, cadmium, calcium, cerium, chromium, cobalt, erbium, hafnium, holmium, lanthanum, magnesium, neodymium, nickel, osmium, praseodymium, rhenium, ruthenium, scandium, thallium, titanium and yttrium. The (001 planes of H.C.P. metals are the primary slip planes of this crystal system. Grain orientation in the melt spun zinc was therefore such that tensile stress along the wire produced nearly minimal shear stress along the (001 slip planes.

In contrast, grain size in the commercially die drawn material was larger and (001) slip planes in the drawn material has been brought into close register with the 45 maximum shear stress plane by the drawing process.

Filaments of H.C.P. metals and their alloys wherein the 001 axis are preferentially oriented at an angle greater than to the filament axis are novel. The crystalline orientation achieved is a result of the high cooling rates (greater than 10 C/sec) achieved in the present invention coupled with preferential growth of H.C.P. metals in the 1 10 direction.

At lower cooling rates, the inclination of the 00] axis to the filament axis would become smaller. The preferred H.C.P. metals in accordance with the present invention are beryllium, cadmium, cobalt, magnesium, titanium, zirconium and zinc.

EXAMPLE 6 The apparatus of FIG. I was charged with a series of pure metals and alloys and filaments were melt spun of these. The alloys and spinning conditions are listed in Table 1. Alloys previously described in Examples 1-5 are notincluded.

TABLE 1 Spinning Velocities 180-260 cm/sec.

Spinning Velocities l80-260 cm/scc.

Melt Temp.. Quench Quench Filament Alloy C. Medium" Temp. C Diam. In.

Iron

ll0 Steel I580 ZnCl- 62 0.006

(010% C. 0.45% Mn) Cobalt (0.6'7! Ni. 0.27z Fe) l550 ZnCI: -62 0.006 Nickel (99.971) 1500 ZnCl: 62 0006 Silicon (97'/1 1500 ZnCl- 62 0.006 Manganese (00571 Fe) I300 MgCl 33 0.006 Copper 99.95% Cu. 0.04% O 1 I00 MgCl 33 0.006 997: Cu. l7! Cd ll00 MgCl 33 0.006 Gold (99.97:) I I00 NaCl 20 0.006 Aluminum ll00 Alloy (99.0 "/1 Al) 680 water 0005-0060 6063 Alloy 680 water H) 0005-0030 (0.7% Mg, 0.4% Si) Magnesium AM l00A Alloy 625 water I 0008 (I071 Al. 0.1% Mn) Zinc AC 4|A Alloy 450 water H) 0.0l2

(471 Al. Wt Cu.

Lead (99.9%) 350 water l- 0.006 Lead-Tin Solder 220-280 water l-20 0005-0030 (5071 Pb. 5071 Sn) Tin (99.9%) 235-600 water l-20 0.006-0.0l2

"Alloy contents are expressed in weight lr. "Quench media:

ZnCI 5| wt. 7: Aqueous Zinc Chloride MgCI 21.6 wt. /r Aqueous Magnesium Chloride NaCl 23.3 wt. 7: Aqueous Sodium Chloride The following examples illustrate chemical stabilization of a molten jet in a liquid medium.

EXAMPLE 7 An 8 mm quartz tube whose end was drawn out into a fine tip of 0.015 cm [.D. was charged with the same copper metal of 99.95 percent purity cited in Table l. The quartz tube was mounted over the quench fluid reservoir in the same position but in place of the melting chamber illustrated in FIG. 1. The tip of the quartz tube was 0.2 cm above the surface ofa 23.3 weight percent sodium chloride quench fluid maintained at 20 C. The top of the standpipe was 2 cm below the surface of the quench fluid. Fluid velocity in the standpipe was 220 cm/sec.

The copper was melted in a helium atmosphere and the melt extruded from the quartz tube at 1 100 C., 220 cm/sec. The molten copper traversed the air gap and entered the quench fluid. The molten jet was disrupted in the quench fluid and solidified as discrete spheroidal particles. In contrast to the result cited in Table I using a magnesium chloride brine at C., copper filaments were not obtained with the less rapid quenching afforded by sodium chloride brine at 20 C.

EXAMPLE 8 The quartz tube of Example 7 was again charged with copper of 99.95 percent purity. The copper was melted in a helium atmosphere and the melt extruded at 1 100 C., 220 cm/sec. The tip of the quartz tube was 0.2 cm above the surface of a quench fluid consisting of 23.3 weight percent sodium chloride and 10 weight percent Na S'9H O maintained at 20 C. The standpipe position and fluid were as in Example 7.

The molten copper-jet traversed the air gap, entered the quench fluid and was solidified as a 0.0l 5 cm diameter filament. The surface of the filament was covered with adark deposit identified as copper sulfide. The

formation of a copper sulfide film on the molten jet within the quench fluid had increased the stability of the jet to the point where solidification in filamentary form could be effected.

Various modifications and variations of the present invention are possible without departing from the spirit or essential characteristics thereof. The present embodiment is therefore to be considered in all respects illustrative and not restrictive, the scope of the invention being indicated by the appended claims and all changes which come within the meaning and range of equivalency are intended to be embraced therein.

1 claim:

l. A method of making filaments from normally solid metal which comprises the steps of:

a. melting said metal;

b. extruding a molten filament of the molten metal;

c. passing said molten filament in sequence (1 through a controlled gaseous interface zone and (2) into a liquid quench zone, said quench zone comprising a liquid medium which is flowing cocurrently with and essentially at the same velocity as the filament introduced therein; and

d. recovering the solidified filament.

2. The method of claim 1 wherein the flow rate of the liquid of said quench medium at the point where the molten filament is introduced therein is substantially equal to the rate of movement of the filament passing into the quench medium.

3. A method for forming filament from a melt of normally solid metal which comprises:

a. melting the metal;

b. forming a free jet of the molten metal in a controlled environment interface;

c. traversing the free jet through said interface into a fluid quench medium flowing cocurrently with and essentially at the same velocity as the jet; and

d. collecting said metal from said quench medium in solid filamentary form.

4. The method of claim 3 wherein said quench medium comprises a liquid which provides a high heat flux regime to exist along the interface with the molten jet and the heat flux is at least 0.4 cal/sq. cmC-'sec.

5. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 700 C. and the fluid quench medium is water at a temperature of from about -20 C.

6. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 1000 C. andthe fluid medium is an aqueous sodium chloride solution at a temperature of less than 0 C.

7. The method of claim 3 wherein the jet temperature of the free jet of molten material is less than about 1500 C. and the fluid medium is an aqueous magne- 14 sium chloride solution at a temperature of less than 20 C.

8. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 2000 C. and the fluid medium is an aqueous zinc chloride at below -30 C.

9. The method of claim 3 wherein the molten material is a metal or metal alloy.

10. The method of claim 3 wherein the quench medium has a chemical reactivity with the molten jet sufficient to form a stabilizing film on the jet.

11. The method of claim 10 wherein the quench medium comprises an aqueous solution containing a sulphide ion and the molten metal is an alloy containing at least 50 weight percent copper.

Claims

1. A method of making filaments from normally solid metal which comprises the steps of: a. melting said metal; b. extruding a molten filament of the molten metal; c. passing said molten filament in sequence (1) through a controlled gaseous interface zone and (2) into a liquid quench zone, said quench zone comprising a liquid medium which is flowing cocurrently with and essentially at the same velocity as the filament introduced therein; and d. recovering the solidified filament.

3. A method for forming filament from a melt of normally solid metal which comprises: a. melting the metal; b. forming a free jet of the molten metal in a controlled environment interface; c. traversing the free jet through said interface into a fluid quench medium flowing cocurrently with and essentially at the same velocity as the jet; and d. collecting said metal from said quench medium in solid filamentary form.

4. The method of claim 3 wherein said quench medium comprises a liquid which provides A high heat flux regime to exist along the interface with the molten jet and the heat flux is at least 0.4 cal/sq. cm-*C-sec.

5. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 700* C. and the fluid quench medium is water at a temperature of from about 0*-20* C.

6. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 1000* C. and the fluid medium is an aqueous sodium chloride solution at a temperature of less than 0* C.

7. The method of claim 3 wherein the jet temperature of the free jet of molten material is less than about 1500* C. and the fluid medium is an aqueous magnesium chloride solution at a temperature of less than -20* C.

8. The method of claim 3 wherein the temperature of the free jet of molten material is less than about 2000* C. and the fluid medium is an aqueous zinc chloride at below -30* C.

9. The method of claim 3 wherein the molten material is a metal or metal alloy.