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Presentation
on
Powder Methods
VIJAY
2008AMD2925
Introduction

Manufacturing process in which fine powder of
materials are Blended or mixed,
 Compacted (pressed) in to required shape, size and surface
finish
 Sintered (heated)
 Controlled atmosphere to bond the contacting surfaces of
particles and to achieve required properties like strength,
density etc.


High quality, complex parts to close tolerances in an
economical manner (eliminating additional machining or
finishing operations ).
Controlled degree of density, porosity, strength and
other properties of material, with minimum waste
Applications
Application
Abrasive
Aerospace
Automotive
Electronic
Joining
Magnetic
Manufacturing
Nuclear
Metals
Fe, Sn, Zn
Al, Be, Nb
Cu, Fe, W
Ag, Au, Mo
Cu, Fe, Sn
Co, Fe, Zn
Cu, Mn, W
Be, Ni, W
Uses
Cleaning, abrasive wheels
Jet engine, heat shield
Valve insert, bushing, gears
Diode heat sink
Solder, electrode
Relay, magnets
Dies, tools, bearings
Shielding, filters, reflector
Table1:- Application of powder methods [1]
Tungsten lamp filaments, oil-less bearings, automotive transmission
gears, electrical contacts, nuclear power fuel elements, aircraft brake
pads, jet engine components, printed circuit boards, explosives,
welding electrodes, rocket fuels, etc [2]
Production of a component
1.
2.
3.
4.
5.
Production of powder
Preparation of powder including blending and
mixing
Compacting
Sintering
Post sintering treatment [3]
Production of Powder
1. Mechanical method (milling)
 Ball mills and roller mills
 Ferrous and non ferrous materials
 Brittle
Fig 1:- Ball mill
Image courtesy: - Ref. [4]
Production of Powder
2. Electrolytic Deposition
 Spongy or powdery state of metal
 Suitable conditions; composition and strength of the
electrolyte, temperature, current density, etc
 Copper, chromium and manganese powders
 Pure powder
Fig 2:- Electrolytic deposition
Image courtesy: - Ref. [2]
Production of Powder
3. Reduction of ores

Iron powder
4. Atomisation


Liquid metals – Orifice- Jet stream of gas, water, or
steam –Broken into fine particles
To control particle size distribution Parameters; design and configurations of the jets, pressure
and volume of the atomising fluid, thickness of the stream
of metal, etc

Production of iron, tool steels, alloy steels, copper, brass,
bronze and the low-melting-point metals, such as
aluminium, tin, lead, zinc, cadmium powders. [2]
Fig 3:- Vertical gas atomization unit
Image courtesy: - Ref. [5]
Preparation of powder
Blending and Mixing
To obtain desired properties and characteristics we
have to mix

 Powder of different materials -different grades and sizes-
different composition
 Lubricants and binders.
 Alloying elements
Fig 4:- Powder contents
Image Courtesy: - Ref. [2]

Compacting
 Loose powder of material is compressed and densified –Green
compact- At room temp.
 Mechanical, hydraulic and pneumatic presses.
Fig 5:- Compaction sequence
(1) Cycle start
(2) Charge die with powder
(3) Compaction begin
(4) Compaction completed
(5) Ejection of part
(6) Recharging die
Image Courtesy: - Ref.[2]

Sintering
 Green compact is heated in a controlled atmosphere
 Below the melting point but high enough to permit solid
state diffusion
 Held for sufficient time to permit bonding of the particles
 Sintering temperature range for iron-based alloys is
1100-1150°C and the time varies between 10 and 60
minutes, depending on the application [6]
Fig 6:- Sintering process
Image Courtesy: - Ref. [7]
Post sintering treatments
Machining
 De-burring
 Joining
 Heat treatment
 Double Pressing
 Oil Impregnation

Advantages of the powder methods
 Complex
shapes can be produced.
 Close dimensional accuracy with elimination
or reduction in machining.
 High production rate due to automation.
 Wide range of properties like density, porosity
and particle size can be obtained.
 No waste during fabrication.
 Highly skilled labour is not required. [8]
Disadvantages and limitations
Pure metal powders are very expensive.
 Size of part produced is limited.
 Alloy powders are not easily obtained.
 Strength properties are lower than product
manufactured by convention way.
 Increased tendency to oxidation due t pores.
 Poor plastic properties like impact strength,
elongation etc.
 High pressure and severe abrasion involved in
process increase the die cost. [8]

References:1.
2.
3.
4.
5.
6.
7.
8.
Manufacturing Engineering and Technology
by Seropr
Kalpakjian and Steven R. Schmid , Chapter 17, Table 17.1 Page
461
http://www.turktoz.gazi.edu.tr
Manufacturing Engineering Processes by Leo Alting, Chapter
9, Page 281-299
http://www.ktf-split.hr/glossary/image/ball_mill.gif
http://www.xstreamscience.org/H_Glaze/assets/Powder%20A
tomizer.gif
http://www.substech.com
http://www.azom.com/details.asp?ArticleID=132
Elements of Workshop Technology by S.K. and A.K. Hajra
Choudhury, Chapter 12, Page 431-440.
Thank You…….