DE2413973B2 - PROCESS FOR THE PRODUCTION OF METAL PARTICLES IN POWDER FORM BY MELTING A WIRE - Google Patents

Description

The invention relates to a process for the production of metal particles in powder form from one themselves consuming metal wire and a device for carrying out the same.

Fine metal powder is increasingly being used to manufacture parts using powder metallurgical processes. Many methods of making metal powders have been proposed. These methods include the atomization of a molten metal by gas jets (US Pat. No. 28,718) or by means of high pressure water (US Pat. No. 33 25 277). Another method is based on spraying molten metal into a vacuum to form individual particles (US Pat. No. 3,510,546). The evaporation of metal in a vacuum and subsequent condensation (US-PS 30 49 421) belongs to this process. Furthermore, it is possible to produce metal powder by melting metal by means of an arc and then forming condensed droplets which emerge from the zone of the arc are brought out, either by means of a gas stream (US-PS 27 95 819 and (US-PS 11 33 508) or by means of centrifugal force alone (US-PS 30 21562 and US-PS 28 97 539) or together with the influence the inherent magnetic repulsion (US-PS 19 97 577). Finally, it is also possible, for the purpose of producing the metal powder, to form a molten surface on a metal rod and to set the molten metal in motion at an ultrasonic frequency, which is either generated by an ultrasonic transducer or which is caused by the use of a high-frequency electrical current which is produced with a strong direct current magnetic field g ekoppel isi (US-PS 32 75 787).

It is also known to produce glass beads by passing an electric current through a A flow of molten gals is passed through, so that an arc is created, whereby the flow is err Area of the arc to the action of a magnetic field: it is exposed to an electromagnet (US-PS 33 13 608). In this last-mentioned process, the interaction generates the magnetfei the, on the one hand by the current conducted in the glass and on the other hand by the electromagnet are caused, intermittent build-up and breakdown of the arc, dei in turn causes a violent movement of the current and thus to the formation of the glass pearls leads.

In some of these known devices there is; Process either in the presence of an inert Gases (US-PS 27 95 819, US-PS JO 21 562 and US-PS 75 787) or in a vacuum (US-PS 35 10 546 U.S. Pat. No. 3,049,421 and U.S. Pat. No. 2,897,539).

The invention is based on the object of fine; Forming metal powder from a wire. This task is solved by the subject matter of the main claim.

The invention thus succeeds in creating one

fine metal powder from a wire by forming particles of molten metal and these Particles are removed by the interaction of two magnetic fields acting at right angles to each other will. The operation can be carried out in a vacuum chamber or in an inert gas atmosphere, whereby the risk of contamination, for example the formation of oxides, is avoided.

The invention provides a process for the preparation of metal particles in powder form of a will be created \ o consumable metal wire, wherein the wire is electrically melted soft characterized in that the metal wire is introduced continuously into a first magnetic field in the direction of and in Contact with an electrically conductive rotatable disk, the peripheral surface of which rotates inside the magnetic field, during which supply a direct current potential is continuously applied between the wire and the disk, so that the flow of a direct current is caused in the wire, which serves to generate a second To generate a magnetic field substantially perpendicular to the first and that melt droplets are formed as a result of (a) the electrical potential between the wire and the disk, (b) the wire feed at a predetermined speed, and (c) the rotation of the disk , and that metal particles after cooling The melt droplets are formed when they are forced out of the contact zone between the wire and the disk by the interaction of the first and second magnetic fields.

The drawing of a special embodiment serves to further explain the invention. It shows

F i g. 1 is a front vertical view, partly in section, of an apparatus showing features of FIG Invention are realized,

F i g. 2 is a vertical section along the line 2-2 of FIG. 1, with the cooling water pipes and electrical Connections are omitted,

F i g. 3 is a horizontal section along line 3-3 of FIG. 1 and

F i g. 4 is a perspective view of the electromagnet and the water-cooled copper connections; which are used in the invention.

A disc 10 provided with a deep groove is arranged in the gap 12 of an electromagnet 14 which is excited by a coil 16. The disk is rotatably supported on a water-cooled shaft 18. The wave 18 is driven by a motor 20 via a pulley. Each end of the shaft 18 is with in the Drawing, not shown, provided vacuum-tight connections allowing rotation. the Disc 10 is supplied with current from a suitable direct current source via a sliding or collector ring 22 fed. The collector ring 22 is held on the shaft 18 in contact with a carbon brush 24, which is in turn connected via the conductor 25 to the negative pole of the power source.

A wire spool 26 is rotatably supported in a frame 28. A metal wire 30 that is a chemical Composition that is to be obtained in the finished powder is provided by the coil of wire a conventional wire feeder 32 is withdrawn, which is driven by a control motor 34 will. The control motor 34 is controlled by an electronic controller 36, which via a Knob 37 can be adjusted. The wire 30 is passed down through a guide tube 38, which is water-cooled by the housing 40. The electrical current is fed to the wire 30 by the Direct current source is supplied via the guide tube 38, which is connected to the positive PoS by means of a conductor 41 connected to the power source.

Therefore, when the tip 42 of the wire 30 contacts the disk 10, a closed circuit of FIG the positive connection of the power source via the conductor 41, the guide tube 38, the wire 30, the tip 42, the disc 10, the shaft 18, the collector ring 22 to the carbon brush 24 and via the conductor 25 to the negative pole of the power source.

When the wire 30 contacts the disk 10, the action between the advancing tip 42 and the Disc 10 flowing current a melting of the tip 42. The melting action and the rotation of the disc 10 leads to an interruption of the contact between the wire 30 and the disc 10, so that it is formed an arc is coming. The arc creates a high temperature, which is an additional part of the continuously advancing wire melts. The end of the continuously advancing wire melts. The end of the continuously advancing wire again touches the rotating disk so that the arch is deleted. The tip of the wire melts and the combined effect comes from the Melting and the rotation of the disk 10 once again cause a break in contact and a new formation of the bow. This generation and interruption of the arc with the associated formation of the Melt droplet 47 continues at a relatively high rate.

The flow of electrical current through the wire 30 creates a magnetic field around the wire 30 Consistent with the well-known principles of electromagnetism. The feeding device of the wire is substantially perpendicular to the axis of rotation of the disk 10 and further essential perpendicular to the magnetic lines of force, not shown in the drawing, in the gap 12 between Pole pieces 44 and 46 of the electromagnet 14.

The generated melt droplets 47 are from the contact area between the metal wire and the Disk pushed out due to the interaction between the magnetic fields, which on the one hand by the electric current flowing in the wire and, on the other hand, perpendicular thereto from the electromagnet be generated.

In Fig. 2 is the direction with which the melt droplets 47 due to the interaction of the two magnetic fields are ejected by the directional arrows reproduced which from the perspective of the drawing from right to left and in general run perpendicular to the axis of rotation of the disk 10. In the illustrated embodiment, the pole piece delivers 44 the north pole and the piece 46 the south pole of the magnet. A reversal of these poles causes the molten particles from left to right and generally perpendicular to the axis of rotation of the disk 10 are expelled. This shows that the direction with which the molten particles are driven out by the interaction of the magnetic fields and not by the direction of rotation of the Disc is determined.

As soon as the individual melt droplets 47 reach the point of contact between the wire 30 and the Have left disk 10, there is no further driving force which accelerates it, since there are no currents

flow through them so that no lines of magnetic force run around each of them as they do from the one through The current flowing through the wire can be generated in the above manner. As most of the from the point of contact repelled particles are in the molten state and thus above their Curie point Moreover, they are not magnetic, so that they are also not affected by the pole pieces 44 and 46 of the electromagnet 14 be attracted.

However, there are some particles that cool off quickly. These particles are carried by the pole pieces 44 and 46 of the electromagnet 14 are attracted and collect on this. If not any Measures are taken to remove these particles, they quickly bridge the gap 12 so that they interrupt the trajectory of the other particles flying away. To overcome this problem it is possible to use one or the other or both of two of the devices described below use. The first device consists in the arrangement of two water-cooled copper connections 48 and 50 on the upper surfaces of the pole pieces 44 and 46. which by means of a cement 52 in place which is resistant to a high temperature. A 110 V AC voltage applied. The connections serve to create some bridge of agglomerated powder particles burn out which could form across the gap 12.

A second device, the effect of which is to keep the gap 12 free of solidified metal particles to hold, which the poles 44 and 46 could bridge, consists of one with a deep recess provided copper «.hcibe 54, which can be rotated in the Inside the gap 12 of the F.lektromagneten 14 and in close proximity to the disc 10 is arranged. The axis of rotation of the disk 54 is parallel to that of the disk 10. The direction of rotation of the Disk 54, however, runs in the opposite direction to that of disk 10, as shown by the directional arrows 55 and 57 is shown. The adjacent edge surfaces of the two disks move generally into the same Direction, d. H. in Fig. 2 from right to left. the Pulley 54 is set in rotation via a pulley 56 which is driven by motor 20 is driven. For driving the disk 54 in the opposite direction with respect to the disk 10 an arrangement with an intersecting transmission belt is used.

The disk 54 is mounted on a water-cooled shaft 58. Rotation Allowing Links 60 and 62 serve both as a support bearing and as a device for introducing cooling water through the Interior of the shaft 58 provided with a bore. The disc 54 may be made of copper, since this is a Has excellent thermal conductivity and in this way from the flowing through the shaft 58 Cooling water can be kept chilled. One

ίο Abstreifflamme 64 is in close proximity to the Inner surface of the recess in the copper washer 54 to prevent metal powder particles from settling fix there.

The melt droplets 47, which from the contact area between the continuously advancing Wire 30 and the rotating disc 10 are expelled rapidly solidify in a general manner spherical shape, varying in size from approximately 0.0254 mm to 0.127 mm in diameter. These Particles collide with a sloping wall 68 and are collected in a container 70, from where they be removed periodically.

In the preferred embodiment, the disk 10 is made of graphite. However, it would also be possible they are made of metal of the same chemical composition as the final powdered product to manufacture.

The entire device can be mounted in a vacuum chamber 66 having a vacuum outlet 67 connected is. The chamber can consist of a conventional sluice container which is hinged provided and sealable doors 72 at each end. There can be viewing windows in different places 74 as well as vacuum-tight electrical and cooling water connections 76.

In the normal embodiment, the material to be pulverized is in the form of a metal wire before. However, it would also be possible to use a wire rod with a significantly larger diameter a suitably modified feed mechanism continuously towards the rotating disk 10 feed, this also for receiving such a rod with a larger diameter would be modified accordingly. It goes without saying.

that under the term "wire" as used above, not only metal in flexible Wire form is to be understood, but also metal in the form of solid rods with diameters that a multiples of 2.54 cm.

For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. A process for the production of metal particles in powder form from a consumable metal wire by electrically melting this wire, s characterized by a continuous supply of the metal wire in a first magnetic field in the direction of and in contact with an electrically conductive rotatable disk, the edge surface of which is inside of the magnetic field rotates by continuously applying a direct current potential between the wire and the disc simultaneously during this supply so that a direct current flows in the wire to produce a second magnetic field which is substantially perpendicular to the first, by producing Melt droplets as a result of (a) the electrical potential between the wire and the disk, (b) a wire feed at a predetermined speed, and (c) a rotation of the disk, as well as the formation of metal particles by cooling the melt droplets as they emerge from the wire disks -Con due to the interaction between the first and the second magnetic field and then collected in a container. 2. The method according to claim 1, characterized in that that work is carried out under vacuum. 3. Apparatus for performing the method according to claim 1, characterized in that a regulatable Metalldrahtzufühmng (26, 34, 36, 37) carries a wire supply for the purpose of introducing the same in a first magnetic field towards and in contact with an electrically conductive rotatable Disc (10), the edge surface of which rotates through the magnetic field, that a device for Erzeu generation of melt droplets from the wire, eir direct current potential between the wire and the Disc with a second, substantially perpendicular to the first magnetic field Magnetic field applies and means (19, 20) for rotating the disc (10) contains 4. Apparatus according to claim 3, characterized by a device (14, 16) for evocation a magnetomotive force for generating the first magnetic field across a gap in one perpendicular to the wire feeder direction, the disc (10) with its Edge in this gap is rotatably supported about an axis which is substantially parallel to the Lines of force of the first magnetic field runs 5. Apparatus according to claim 4, gekennzeichnei by at least one means (48, 50) for removing particles magnetically attached to the Gap delimitation surfaces of the magnetomotive force generating device attracted with first and second copper terminals attached to these surfaces and mi ·: AC connections are provided. 6. Apparatus according to claim 4, characterized by a device for removing particles which are magnetically attached to the gap delimiting surfaces of the device generating the magnetomotive force be attracted to a second disc (54) which is rotatable in the first magnetic field axially parallel and at a small distance from the first disc (10) and held in the opposite direction Direction to the disc (10) is rotatable.