Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
  • B22F9/00—Making metallic powder or suspensions thereof
  • B22F9/02—Making metallic powder or suspensions thereof using physical processes
  • B22F9/06—Making metallic powder or suspensions thereof using physical processes starting from liquid material
  • B22F9/08—Making metallic powder or suspensions thereof using physical processes starting from liquid material by casting, e.g. through sieves or in water, by atomising or spraying
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
  • B22F9/00—Making metallic powder or suspensions thereof
  • B22F9/02—Making metallic powder or suspensions thereof using physical processes
  • B22F9/06—Making metallic powder or suspensions thereof using physical processes starting from liquid material
  • B22F9/08—Making metallic powder or suspensions thereof using physical processes starting from liquid material by casting, e.g. through sieves or in water, by atomising or spraying
  • B22F9/082—Making metallic powder or suspensions thereof using physical processes starting from liquid material by casting, e.g. through sieves or in water, by atomising or spraying atomising using a fluid
  • B22F2009/086—Cooling after atomisation
  • B22F2009/0864—Cooling after atomisation by oil, other non-aqueous fluid or fluid-bed cooling
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B22—CASTING; POWDER METALLURGY
  • B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
  • B22F2999/00—Aspects linked to processes or compositions used in powder metallurgy

Definitions

• the present invention relates to the manufacture of metallic granules. Its main object is a method for manufacturing metallic granules and it extends to the products obtained in accordance with this method as well as to a device particularly suitable for implementing this method.
• the invention is applicable for putting any metal in the form of granules, by including in this concept, not only pure or almost pure metals, but also metal compositions or alloys.
• the objective is to obtain practically spherical grains, of diameter for example of the order of 0.1 to 5 mm, together forming a powder which is pourable, easy to transport by pneumatic means, and which has a relatively apparent density. high, without great porosity, with in addition the possibility of obtaining a uniform grading of the grains, possibly after an easy sorting.
• the invention provides a method of manufacturing metal granules of the type in which the metal in the form of granules is solidified from the molten metal, characterized in that a jet of molten metal, it is passed through a vibrating orifice to divide the jet into individual drops, and the cooling causes the solidification of these drops into granules.
• the method according to the invention can be applied to the manufacture of metallic granules from molten metal baths of any composition. It will however be observed that most often the treated metals are in the molten state at a temperature of between 200 and 1500 ° C. and that the vibrating orifice through which the jet of molten metal exits generally opens into an atmosphere cooled by heat loss. in the ambient air, the temperature of which can therefore be between 20 and 9 ⁇ ° C. for example. In practice, operation is advantageously carried out under conditions such that the temperature difference between the molten metal when the jet is formed and the atmosphere in which the vibrating orifice opens is at least of the order of 200 ° C., and preferably between 300 and 1300 ° C, and more particularly between 500 and 1000 ° C.
• the drops of the jet are made to fall by gravity through an atmosphere of inert gas maintained at a temperature below the ternpéra-ture of solidification of the molten metal.
• the inert gas atmosphere can be chosen according to the nature of the metal, the diameter of the jet and the pressure conditions at the level of the vibrating orifice, so that the drops formed quickly reach the limit fall speed, over a drop height left available in the atmosphere which is sufficient to allow complete solidification of the granules before their collection.
• the fall speed can for example be of the order of 2 to 30 meters per second and, depending on the thermal conditions, solidification can take a time corresponding to a fall height of the order of 10 cm to 20 m, or preferably 20 cm to 10 m.
• the metal drops are subjected to internal forces which result from the vibrations communicated at the time of the division of the jet into drops at the outlet of the vibrating orifice.
• the invention thus makes it possible to obtain powders of granules in which the diameters of the granules can be for example of the order of 0.2 to 3 mm, with dispersions relative to the average size which can remain less than + 0 , 5 mm, or even not to exceed approximately + 0.01 mm.
• the powders obtained also have surface qualities which are generally favorable to the properties which are sought in this type of granules, in particular a surface hardness and a resistance which contribute to the good conservation of the powder and its flowability.
• the inert gas can be for example helium, argon or mixtures of these gases. In certain cases, it may be advantageous to further ensure a dispersion of the metal drops during solidification with respect to the direction of fall of the jet, so as to prevent individual drops from being able to merge during solidification.
• the bath used can advantageously consist of a molten halide of at least one metal of the molten metal mass. It can also consist of a molten halide of at least one additional metal more reducing than the essential metal of the granules and incorporated in small proportion in said mass.
• Such an additional metal may in particular be calcium, a metal whose oxide readily dissolves in a bath of fluoride and / or calcium chloride.
• a proportion of calcium of the order of 0.5 to 10% by weight is generally sufficient in metals such as aluminum or magnesium for example.
• metals such as aluminum or magnesium for example.
• the additional metal can be found in the granules obtained in accordance with the invention, while the recommended processing conditions make it possible to prevent the molten salts being found there other than in the trace state, detectable but not annoying, and in particular the invention makes it possible to produce granules of reactive metals such as calcium, magnesium or aluminum which, despite the use of a bath of molten salts, do not exhibit any hygroscopicity which is detrimental to preservation and. flowability of powders.
• the manufacture of metallic granules involves the use of a device comprising a metal melting furnace in a receptacle for receiving a mass of molten metal, means for forming a jet of metal taken from said mass, through a vibrating orifice, means for causing the vibration of said orifice and thus ensuring the division of the jet into individual drops, and a chamber for cooling and solidifying the metal coming from said orifice, over at least the distance traveled by the drops during their solidification.
• the device comprises a siphon for removing metal from a mass of molten metal separated from a bath of molten salts by decantation in said container.
• said container and. said cooling chamber are preferably sealed and means are advantageously provided for separately adjusting the pressure of an inert gas in said container and in said cooling chamber.
• FIG. 1 shows schematically in section the various organs of the device according to the invention in a first embodiment
• FIG. 2 represents such a device, also in vertical section, in a second embodiment
• Figure 3 shows in more detail the device of Figure 2 in its upper part.
• the device comprises a heating cell provided with a sealed enclosure forming a container and heating means, a member for introducing raw materials into the cell, a cooling in communication with the cell by a conduit comprising a siphon and a zone pierced with at least one vibrating orifice, a first pneumatic means for establishing and controlling the pressure of the atmosphere in the enclosure, a vibrator connected to the zone comprising the vibrating orifice and arranged so as to make it vibrate continuously, a second pneumatic means for establishing and controlling the pressure of the atmosphere contained in the cooling chamber, and a device for evacuating the solid from this chamber .
• the device shown in FIG. 1 comprises a closable member for introducing material 1 for bringing the metal into a heating cell 2 from which the molten metal is injected into a cooling chamber or tower 3 through a conduit 4
• a closable evacuation device 5 makes it possible to evacuate the solid metal granules formed in the cooling tower 3.
• the heating cell 2 comprises a sealed enclosure 6 forming a container for containing the molten metal.
• This enclosure 6 is heated by an oven 7 surrounding its side walls and maintaining inside the enclosure a temperature higher than the melting temperature of the metal.
• the molten metal 8 occupies the lower part of the enclosure 6; it is surmounted by a gaseous atmosphere 9, the pressure of which is controlled by a first pneumatic means 10 to which it is connected by a pipe 23.
• This pressure in the atmosphere 9 can be increased or decreased, causing more or less rapid injection of the molten metal 8 through the conduit 4.
• This conduit consists of a curved tube 11, one end 12 of which is immersed in the molten metal 8 and the other end of which 13 penetrates vertically into the upper part of the cooling tower 3.
• the upper part of the tube, near the end 12, is bent to form a siphon, the elbow protruding from the level of the molten metal.
• the end 12, the mouth of which is turned towards the bottom 14 of the enclosure 6, is provided with a filter 15 intended to retain the impurities contained in the molten metal.
• the area of the enclosure 6 in the vicinity of the bottom 14 is a settling area where impurities of higher density can accumulate than the rest of the liquid.
• the filter can be placed just above this settling zone of the molten metal to prevent suspended solid inclusions from quickly clogging the filter.
• the heating cell 2 further comprises a mechanical stirring means diagrammatically represented by the propeller 18, ensuring stirring and homogenization of the liquid.
• the end 13 of the tube 11 ends in at least one orifice for the injection of the molten metal into the cooling tower 3.
• the filiform flow of molten metal thus obtained forms a jet in vertical drop to which vibrations are applied to produce uniform liquid drops.
• the end 13 of the tube is driven by vibrations by a vibrator 16 and a connecting device schematically represented by the rod 17.
• the drops of molten metal formed at the end 13 of the conduit 4 are dispersed in the cooling tower by a dispersing means 19. It is for example an annular electrode surrounding the jet and electrically charged with respect to the end 13 of the tube 11, which causes on the drops the appearance of electrical charges all of the same sign.
• the drops of liquid disperse away from the vertical direction of the jet and they solidify before falling back to the bottom 20 of the tower 3.
• the latter contains a gaseous atmosphere allowing the rapid cooling of the metal and inert with respect to of it. It may include different means for accelerating the cooling of the metal, for example means for circulating the gas.
• the cooling rate of the drops can condition the nature of the phase of the material. riau solidified and, thus, the quality of the product obtained.
• the use of a sealed cooling tower prevents communication of its internal atmosphere with the ambient air.
• the pressure of the gaseous atmosphere of the tower can be controlled by a second pneumatic means 25 to which it is connected by a pipe 24.
• the metal introduction member 1 includes a communication lock 21 and the evacuation device 5 includes a lock 22, to allow the continuous operation of the installation.
• the raw material supply device 1 makes it possible to bring into the heating cell either molten metal or metal in the solid state; in the latter case, the melting takes place in the heating cell, and the metal is only injected into the cooling tower when it is fully molten and homogeneous. It is possible to treat metals which react with oxygen, since the hermetic assembly comprising the heating cell 6, the pressure control means 10 and 25, the communication conduit 4 and the cooling tower 3 can be subjected to a controlled atmosphere of gas which does not react with the metal.
• the implementation of the invention by means of the device of FIG. 1 consists in introducing the metal into the heating enclosure 6, either in solid form or in liquid form, through the airlock 21, to maintain its temperature slightly above of its melting temperature by the heating means 7, and to homogenize the molten mass by stirring or by bubbling by the stirring means 18.
• the molten mass is homogeneous, it is injected into the cooling tower 3 to through the tube 11 and the vibrating orifice.
• the siphon is primed, for example, by an overpressure of the order of 5 g to 500 g / cm in the enclosure 6, produced by the pneumatic device 10.
• the drops thus formed are dispersed if the elec- annular trode of the dispersing means 19 is under tension, and cooled by the atmosphere of the tower until forming solid spherical granules.
• the injection speed of the molten metal through the vibrating orifices is regulated by the difference in gas pressure between the atmosphere 9 which overcomes this molten metal in the heating enclosure and the atmosphere of the tower 3. This injection speed is controlled and set allows to take into account the nature of the metal, the vibration frequency of the vibrating orifices, and various physical parameters of the molten metal such as its temperature.
• the pneumatic means 10 and 25 thus make it possible to establish, adjust, and stop the flow of injected liquid metal.
• the homogenization of the molten mass can be achieved in different ways. If the inclusions are sufficiently fine, a homogeneous suspension of these particles can be achieved by effective mixing by means 18. If on the contrary the inclusions are large and risk clogging the filter and / or the orifice (s) too quickly injection, a decantation is carried out which is carried out in the lower part of the enclosure 6.
• a bottom 14 may be provided which is substantially and / or partially conical, the top of the cone being directed downward, to cause the accumulation of decantation products in a removable basket, not shown in the figure, placed at the bottom of the cone, the basket can be removed for the evacuation of these decantation products.
• the passage of the basket may be facilitated by an offset, asymmetrical arrangement of the conical bottom 14 and / or of the communication conduit 4 relative to the enclosure 6 to allow the vertical release of the basket without abutting the siphon or the filter 15.
• the device of FIGS. 2 and 3 comprises for the most part the same essential organs as the previous one, but it is designed to allow better than it the manufacture of reactive metal granules, easily oxidized.
• the furnace 31 makes it possible to heat the cell 32 so as to melt and keep the materials introduced therein, as well the metal intended to constitute the granules produced as metal halides constituting the purification bath.
• the cell 32 is equipped to define 1 interior of the oven two separate compartments communicating with each other by a filter 35.
• the embodiment shown in detail in Figure 3 corresponds to the case where a bath of purification salts more dense than molten metal.
• a tubular chimney 36 is disposed vertically in the enclosure 32, the cover 37 of which it passes in leaktight manner, to open to the outside via an airlock 38 for loading the solid products.
• the filter 35 is arranged across the lower end of the chimney 36, above the bottom 39 of the cell 32.
• a first compartment 41 is thus formed by the volume internal to the chimney 36.
• the metal is introduced into solid pieces through the airlock 38 and that its fusion is ensured.
• the metal is protected from oxidation by an inert gas which is admitted into this compartment at 42.
• the other compartment 4 is constituted by the intermediate volume between the chimney 36 and the container limiting the cell 32. Its role is to allow the separation between the molten metal by decantation and the purification bath after it has passed through this bath. I1 thus makes it possible to create in the cell 32 a mass of molten metal 44 in which the sampling will be carried out for the formation of the liquid metallic jet. In the case of the figure, the mass of liquid metal 44 is decanted above the bath of molten salts 45 and it is surmounted by an atmosphere of inert gas introduced into cell 32 at 46.
• the purification salt is present in quantity suf-fisante so that the filter 35 remains always immersed in the bath 45.
• liquids can be forced through the filter 35, either to cause the transfer of the molten metal from the melting compartment 41 to the settling compartment 43, that is to circulate the molten salt through the holes of the filter for cleaning purposes.
• the siphon-forming duct 34 comprises two vertical coaxial tubes sliding the one inside the other.
• the internal tube 4 ⁇ crosses the bottom 39 of the cell 32.
• I1 opens at its upper end into the atmosphere of inert gas which overcomes the mass of molten metal 44, at 47, and it ends at its lower end with l vibrating orifice 48 through which it opens vertically at the top of the tower 33.
• a vibrator has been shown at 49 which acts on the end of the tube 46 and thus causes the jet to be divided into liquid drops as soon as it leaves the orifice 48
• the external tube 51 of the siphon can be moved from outside the cell by means of a rod 52.
• I1 is closed at its upper end and when it is completely lowered it opens by its lower end at ground level fondue 44. Its operation thus makes it possible to prime the siphon and cause the liquid metal to flow through the internal tube 46.
• the jet of liquid metal divided into drops falls into the tower 33 which is filled with an inert gas admitted in 51 and extracted in 52 (figure 2 ).
• the internal atmosphere in the tower cools by heat loss in the ambient air through its walls.
• the height of the tower is sufficient for the drops of liquid metal to solidify completely during their fall.
• the solid granules thus obtained are collected at the bottom of the tower 33 and they are extracted therefrom by an airlock 53.
• the filter 35 having the aim of preventing the passage of any solid inclusion which could block the vibrating orifice 48, has holes of dimension less than or at most equal to that of this orifice, and for example less than 200 microns, for vibrating orifices of diameters which may vary between 200 microns and 3 mm.
• the positive say according to the invention can be constituted differently in other embodiments.
• the shape of the chimney 36 and that of the siphon 34 can be modified to adapt the cell 32 to receive a bath of molten salts of lower density than that of the molten metal.
• the removal of liquid metal then takes place in the mass which settles below the bath of molten salts.
• the production yield of granules can be increased, in an industrial manufacture, by replacing the single orifice 48 by a vibrating plate provided with holes which form separate jets. It is thus possible to form a series of jets in the same cooling atmosphere and at the end of the same sampling device.
• a halide of the metal to be granulated generally a fluoride or a chloride, or a mixture of such salts, or a halide of a more reducing metal, the oxide of which forms preferentially to that of metal to be granulated.
• a halide of the metal to be granulated generally a fluoride or a chloride, or a mixture of such salts, or a halide of a more reducing metal, the oxide of which forms preferentially to that of metal to be granulated.
• a halide of the metal to be granulated generally a fluoride or a chloride, or a mixture of such salts, or a halide of a more reducing metal, the oxide of which forms preferentially to that of metal to be granulated.
• a powder intended for use in aluminothermy was produced from molten aluminum brought to 850 ° C., using in addition a bath of molten cryolite (Na 3 AlF 6 ) to dissolve the alumina.
• the molten aluminum is denser than this bath and is therefore taken from the bottom of the cell.
• the cooling gas was helium.
• magnesium for example, a mixture of magnesium chloride and fluoride is used as the molten salt bath.
• Calcium is widely used for example in refining of cast irons and steels.
• the invention makes it possible to have it in the form of a regular powder of spherical granules which are easy to transport and to dose, without having to incorporate undesirable constituents therein.
• the addition of magnesium to calcium lowers the melting point of the alloy. From 11.5% by weight of magnesium in the eutectic alloy to 28% by weight of magnesium, the temperature to be imposed on the molten alloy is in fact determined by the melting temperature of the salts: 645 ° C. for the CaCl 2 -CaF 2 eutectic. The fusion cell is therefore brought to 700 ° C. for example.
• the same salt bath is used in the context of aluminum granulation.
• calcium in an amount at least stoichiometric for the reduction of the oxygen which it may contain, ie for example 0.5% by weight of calcium for commercial aluminum metal.
• a greater proportion of calcium has been added, so that this calcium is mainly found in the granulated magnesium produced, for example in a proportion of 8% by weight.
• the frequency of the vibrations imposed on the outlet of the jet was 1500 Hz, but we can increase this frequency to 6000 Hz, or use any frequency between 1000 and 16000 Hz.
• the height of fall in the cooling gas was chosen to be sufficient so that there was always complete solidification of the drops during the fall, starting immediately at the outlet of the vibrating orifice, to benefit from the effect produced by the vibration on the drops.
• the following data were used to evaluate the temperature of the cooling gas at 50 ° C and for the temperature of the metal at the vibrating orifice of 70 ° C above the melting point: Limiting speed Solidification height

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• Manufacture Of Metal Powder And Suspensions Thereof (AREA)

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• 1979
  • 1979-12-21 FR FR7932115A patent/FR2471827A1/fr active Pending
• 1980
  • 1980-12-22 WO PCT/FR1980/000187 patent/WO1981001811A1/fr active IP Right Grant
  • 1980-12-22 US US06/296,270 patent/US4428894A/en not_active Expired - Fee Related
  • 1980-12-22 EP EP81900066A patent/EP0048713B1/de not_active Expired
  • 1980-12-22 AU AU66435/81A patent/AU543715B2/en not_active Ceased
  • 1980-12-22 JP JP56500243A patent/JPH0135881B2/ja not_active Expired
  • 1980-12-22 IT IT26884/80A patent/IT1134864B/it active
  • 1980-12-22 DE DE8181900066T patent/DE3066037D1/de not_active Expired

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