Powder Compaction

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Powder Compaction
Introduction
The main purpose of the compacting process is the forming of metal
powders into compacts or desired shape with sufficient strength to
withstand ejection from the tools and subsequent handling up to the
completion of sintering, without breakage or damage
it is the
subsequent sintering operation which imparts the final strength.
Although there are various methods of
powder
compaction, only few of them are widely .employed commercially.
It is convenient to group the various ., methods into the following
classification :
(i)
Pressure-less shaping , technique
(ii)
Cold pressures shaping technique
(iii)
Hot pressures shaping technique
Pressure less Shaping Technique
1) Loose sintering (loose shaping, gravity sintering, or pressure less
Slater log).
In this process, metal powder is poured or vibrated mechanically into
the mold which is a negative impression of the article and heated to the
sintering temperature1. This is the simplest method involving low cost of
equipment. It has been mainly employed to a large extension a
commercial basis for producing product with porosities varying from
30% up to 90% by volume However this process is not used for the
production of complex-shaped parts :
(a) the difficulty of part-removal from the mold after sintering
(b) flow characterieristics of the powder and
(c) considerable amount of shrinkage during sintering.
The die employed in this method must have adequate strength to contain
the powder during sintering and usually carbide, graphite, stainless steel,
or cast iron is used as the die material1.By selecting suitable powder,
sintering temperature and time, it is possible to produce high density part
of most metals and alloys, but in most of the cases, poor dimensional
accuracy is obtained. This method may be employed to produce very
large ingots ( up to 2 tons) from carbonyl iron and nickel powder which
may be further treated by rolling or forging Highly porous filter materials
such as bronze stainless steel, monel, tungsten, ets, are easily formed by
this technique. Extremely porous nickel sheets used as electrodes and fuel
cell and beryllium bars are another application of this process.
1) Slip Casting
Slip casting is commonly used for the production of ceramic
articles, although it may be used to a limited extent for metals. The
slip for casting is prepared from metal or ceramic powder finer
than 5μ a liquid to serve as a suspending medium and a small
amount of suspension agent and defloecatant (which prevents the
settling and aggregation of powder particles and maintains the
desirable viscosity of the slip) and binders, The process consists in
filling the highly absorbent plaster of Paris mold ( made by the
casting around a wooden or metal pattern) with this slip partial
drying in the mold, removal of the " slip casting " from the mold,
drying in an oven and sintering of the compact at the proper
temperature and time in order to achieve the desired properties of
the of the Parties of the sintered materials. Fig. 21 illustrates the
stages of this method.
(a)
(b)
(c)
Fig. 21. Principles of slip casting : (a) Assembled mould: (b) filling the
mould: (c) absorbing water from the slip : (d)
finished plece, removed from the mould and irimmed.
Thus, a casting slip ii a, suspension of particles usually than 5μ and
these are prevented from aggregation or formation particle build-ups
and controlled by the, adjustment of the factor1. A suspending medium
to fulfill the following basic requirements is selected : proper viscosity,
chemical stability, fluidity, and value to allow proper mold filling.
Mostly water is use as the liquid vehicle or suspending medium, but
absolute alcohol and other organic liquids may also be employed. The
most useful additives employed in the preparation of cast able slip are
ammonium and sodium salts of alginic acids such as Marcx and Keltex
because they, serve the three fold functions: act as deflocculant,
suspension agent, and binding agent to improve the green strength of the
compact.
The suspension is made either manually or mechanically. it is
advisable to shake or vibrate the mold while pouring in order to obtain a
high quality product with less final porosity. Various, lubricants may be
employed to prevent the product adhering to the mold walls ; for
example; Spraying a 0.2% solution of sodium alginate onto the internal
mold wall surface ensures easy removal of the product without affecting
the moisture absorption.
It is possible to prepare both low and density articles by this
technique. It has been employed for the production of.. tubes boats,
crucibles, cones, hollows, turbine blades, rocket guidance fins, and other
parts made from Mo, W, Ta mid CT powder. Paris fabricated by this
method usually possess a lower density than of loose sintered
components.
The main drawback of. this process is that it is a relatively slower
and costlier process and therefore not suited, for . mass production of
P/M parts.
3) Slurry Casting
This is a similar to slip casting except that the slurry or cream of the
metal powders with suitable liquids, various additives, and binders is
poured into a mold and lowed to dry before extraction. the solvent
present in It may be removed either by absorption into the mold, often
made of plaster of
Paris or, by slow evaporation. Alternatively,
solidifying liquid resins or self-solidifying liquids may lie used. Another
modification of the process consists in using n non-absorbent mold,
vibrating the cream or slurries in a vacuum, injecting the slurries along
with vibration into the mold and freezing the castings.
The main drawback of this process is the difficulty in obtaining
slurries of sufficiently high density, which can be poured and which will
leave no residue sintering. This is also a slower process and produces
produces with poor dimensional accuracy.
The advantages of slip and slurry cresting are. that the parts can be
produced in various shapes and . sizes which are not possible by the
conventional compaction technique and the expensive dies and
equipment's .are eliminated here.
It is applied to produce turbo super charger bucfet5, very high
porosity sheet (up to 90 volume % porosity) for use as electrodes in fuel
cells and Ni-Cd
rechargeable batteries, etc3.
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