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POWDER METALLURGY

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Title: POWDER METALLURGY


1
POWDER METALLURGY
  • Lecture 8

2
ATOMISATION TECHNIQUES
  • In this process, molten metal is separated into
    small droplets and frozen rapidly before the
    drops come into contact with each other or with a
    solid surface.
  • Typically, a thin stream of molten metal is
    disintegrated by subjecting it to the impact of
    high-energy jets of gas or liquid.

3
Atomisation Technique
  • In principle, the technique is applicable to all
    metals that can be melted and is used
    commercially for the production of iron copper
    alloy steels brass bronze low-melting-point
    metals such as aluminum, tin, lead, zinc, and
    cadmium and, in selected instances, tungsten,
    titanium, rhenium, and other high-melting-point
    materials.
  • Production rate of commercial atomisation units
    are 400 kg/min.

4
Atomisation Technique
  • Gas atomisation
  • Water Atomisation
  • Centrifugal Atomisation

5
GAS ATOMISATION
  • The liquid metal stream is disintegrated by rapid
    gas expansion out of a nozzle.
  • Gas used are air, N2, He or Ar.
  • Application nickel-base superalloys and many
    other highly alloyed materials.
  • There are horisontal and vertical gas atomiser.
  • The particle shape is spherical with a fairly
    wide distribution.
  • The product is homogeneous and has good packing
    properties.

6
Horisontal Gas Atomisation
  • Low temperature atomisers. High velocity gas
    emerging from the nozzle creates a siphon,
    pulling molten metal into the gas expansion zone.
    A high gas velocity aids breakup of the metal.
    During flight through collection chamber, the
    droplets lose heat and solidify.

7
VERTICAL GAS ATOMISATION
  • The melt is prepared by induction melting and is
    poured into the nozzle. The melt must be
    superheated over Tm. The gas jets can be formed
    by multiple nozzles arranged in a circle around
    the melt stream.

8
Operating Variables in the Gas Atomisation
Process
  • The Melt
  • Melt temperature
  • Melt viscosity as it enters the nozzle.
  • Alloy type,
  • Metal feed rate
  • Nozzle geometry
  • The nozzle-to-melt distance
  • The Gas
  • Gas type
  • Residual atmosphere
  • Gas pressure
  • Gas feed rate and velocity
  • Gas temperature

9
The Production Parameters for Ni-based
Superalloy Powder
10
The Formation of Metal Powder by Gas Atomisation
11
Changes of the Droplet Shape
  • The droplet shape sequence, with distance from
    the nozzle, occurs as cylinder cone sheet
    ligament sphere. Depending on the amount of
    superheat and other variables, solidification can
    produce one of these shapes.

12
  • The satellites present (Fig. 3.19 left) are due
    to turbulence and smooth particles (Fig. 3.19
    right) formed by control of the flow near the
    nozzle. The elimination of satellites is
    importand for good packing and flow attributes.

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14
WATER ATOMISATION
  • The most common technique for producing elemental
    and alloy powders from metals which melt lt
    1600oC.
  • High pressure water jets (single jet, multiple
    jets or an annular ring) are directed against the
    melt stream, forcing disintegration and rapid
    solidification.

15
WATER ATOMISATION
  • The process is similar to gas atomisation, except
    for the rapid quenching and differing fluid
    properties.
  • Because of rapid cooling, the powder shape is
    irregular and rough, with some oxidation.
    Chemical segregation within an alloy particle
    tends to be quite limited.
  • Milling may be required after atomisation to
    eliminate particle bonding.

16
Four Possible Particle Generation Mechanisms
  • Particles are generated by cratering, splashing,
    stripping, and bursting mechanism.
  • Bursting mechanism results in the smallest
    powders.
  • Typical mass flow rate 5 kg water/kg metal
    powder.

17
Process Control Variable
  • Water pressure
  • The nozzle-to-melt distance

18
  • A 3.5 carbon steel is water atomised, oxidised,
    milled, decarburised, and annealed to form a
    sponge which is ground to form an iron powder.
  • Other materials produced by water atomisation
    include stainless steel, copper, brass, bronze,
    tool steel, cobalt, nickel alloys, precious
    metals, and low melting temperature metals (Pb,
    Sn, and Zn alloys).

19
A Comparison Between Gas and Water Atomisation
20
Water vs Gas Atomisation
  • The powder shape
  • The surface contamination
  • Oxide coating can be removed by heating in
    hydrogen after atomisation.

21
CENTRIFUGAL ATOMISATION
  • Reason for development of centrifugal atomisation
    is the desire to control particle size and the
    difficulties in fabricating powders from reactive
    metals.
  • Combination of a fusion process and a centrifugal
    force. The centrifugal force throws off the
    molten metal as a fine spray which solidifies
    into a powder.

22
  • A consumable electrode (anode) made from the
    desired material and rotates at velocities up to
    50,000 rpm. The electrode is melted at its end by
    either plasma arc or stationary tungsten
    electrode.

23
Spherical Steel Powder Formed by Centrifugal
Atomisation
24
The Droplet Formation Events
25
Some Examples of Centrifugal Atomisers
26
Atomisation Limitations
27
Forming Specific Metal Powders
28
PRESS-AND-SINTER PROCESS
  • In this process, custom-blended metal powders are
    fed into a die, compacted into the desired shape,
    ejected from the die, and then sintered
    (solid-state diffused) at a temperature below the
    melting point of the base material in a
    controlled atmosphere furnace.
  • The compaction step requires the part to be
    removable from the die in the vertical direction
    with no cross movements of the tool members. The
    sintering step creates metallurgical bonds
    between the powder particles, imparting the
    necessary mechanical and physical properties to
    the part.
  • Conventional PM offers many advantages over the
    other consolidation methods. It offers the lowest
    manufacturing cost, including modest tooling
    costs. It also produces the closest tolerances in
    the finished parts. Since it is a net-shape
    processing technology, it yields parts requiring
    little or no secondary machining operations.
    Lastly, it makes available to designers and
    fabricators a wide variety of material systems
    from which to choose.
  • Parts produced through the press-and-sinter
    process are subject to certain limitations as
    well. Tooling and the maximum press tonnage
    capabilities impose size and shape constraints on
    parts that can be fabricated. Annual production
    quantities dictate how quickly the costs of tool
    set-ups and maintenance can be amortized.
    Finally, the presence of residual porosity in the
    parts will cause certain physical and mechanical
    properties to be lower than those of the wrought
    material.
  • Typical Press-and-Sinter Productsgears,
    sprockets, cams, ratchets, levers, clutch plates,
    pressure plates, housings, pole pieces, bearings,
    bushingsTypical Markets Using Press-and-Sinter
    Partsautomotive, appliances, power tools,
    hydraulics, lawn and garden, agriculture,
    off-road equipment, motors, firearms,
    recreational equipment, hardware, business
    equipment

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