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Structural evolution during mechanical alloying of alumnium-iron powders
Powder production ION BEAM
PROCESSING
Fundamentals OF POWDERS
MODELLING METAL
11.1~.Mullet-, W.J. Ensinger. Ion
‘of powders
is rcvie~rvrd with
to
regard
to
Dutton
Force
ct
Rase,
al.
Ohio.
(Wright-Patterson
Air
Melnl(.
Matrr.
ITSA)
to agitate surfaces
the powder to expose t,) the ion beam.
conducted
using
a continuum
Methods.
including
ion
and
rultb
modified
ion
assisted
Results,
deposition,
concerning
annealing, discussed.
art>
and
dcscribrd.
tadiation
doping and Some examples
Modclling flow
tnicrostructurc consolidation
damage,
properties. arc given.
are
and
ATOMIZATION/
a stress
Poisson‘s
SUBSTRATE
QUENCHING
SOLIDIFIED
POWDERS
OF RAPIDLY
and
which
depend
crrrp.
The
ct
llniversity. rlvr
(Nattonal Tsing
al.
llsinchu.
MPttrli.,
31. No 2, 1995,
Vol
145-153.
(‘cnt.rifugal atomizal iott and substrate quenching have he6.n combined for production
of flaky
of process
paramrtcrs
struc’turt~
arc described.
30 pm thick are
with
reportt~d.
grains
with
powders
of Al. Effects
on particle Particle
aspcc?
sizes of lo-
ratios
St.ruc~tures
on density.
In sintrt
ratio
tW\*ceen
tnotit~l was
PREDICTION
gi\,es
a
is
Pressing
suggcstcd
COMPRESSION
IN
milling
milling.
.Joslin,
K.1I.G.
Birmingham, Mater.
Asttbcc
(l’nivrrsity
Hirtninghanl.
75x,/s.
A, i-1,1 26.4.
No
01
Mrtcrlf.
IlKi).
5,
19%.
1087-1091. that
or Al alloy powders dimensional time
is
to
to large
Full
are suh,jrctcd
reduced
abrasion
encapsulated
c~omprcssiotr,
attributed lead
when
high
of particle
and
Itigh
is
ARTICLES
mclchanical
USING
GAS DRAINAGE
1994,
Development in which gas during
plasticisers t.o
computer
are ensure
Ijensitirs for Fc hasp
l-6.
pressing used.
is
tafficient
of 7.4-7.7 materials.
of compaction frotn a metal reported.
A porous gas
gm.c’m ” are
The
model mill.
of
betwrcbn
predicted of parking
Pow&r
T~l??rt~f.,
199-205. of
is
ENERGIES
is
and density
is
rt~ported
taxpcrimrntal for random
orirntat.ions
close
and nail rtumbcrs
wcxrc drt,rrmined
loosc~ parking.
a
(i.
compositionally
front
ultrafint,
two-step
has
ltowdrrs
sintcring.
tq
at
fclrmrd
STRUCTURAL
EVOLUTION
MECHANICAL
ALLOYING
ALUMNIUM-IRON
Sttx(?ural
600
during
Properties
DURING OF
POWDERS
c\olution
of Al-(1,
increased O.O25at%
t,hc
reduction.
A1-%5%Fc
M. l!%esterc,i (t.:st,av Materialoveho Slovakia)
Pokrok,t~
Al
crystallinr
rat<,
of
was
ratio
ltarticlr
fully
sizcx
amorphous
and Al-lO.‘i”,,Fe
was a mixturt,
and amorphous in all alloys
phases. F’(tAIzj formt,d excrpt Al-2.5’:5Ft~ which
Ftl,Alr,
consolidated rrtnainrd
after
10.7%
of cystallinrB
rntlling.
and
25’:&
Shock powders
nano-ctystallirtt~.
MICROSTRUCTURES
OF ATOMIZED
ALUMINIUM-CHROMIUM
POWDERS
ANDPROPERTIESOFEXTRUDED POWDERS Kobayashi
et
al.
(Osaka
l:rtivrrstty,
Z. M~tnlbkd. Vol X6, No 4. 19!)5,
powders,
cooling
solubility SAV, Kosice.
in
in the ball to powder
accclcrated
A
M. k&d,
“,,Fc
Fe
in t.hta as-niillr,d
Incrclase
were correlated
Vyskumu
of
from the rqriilibrtum value 01 up to 4.4’:,. Nanometer grains
prcscttt
AI-Cr
ALUMINIUM
mechaniaxl
Solubility
2x9-292. The microstructures ACTIVATION
during
4. 7.13, 10.7 or 26)at
investigated.
K.F.
removal. claimed
that
(’ tn N. AlN was
Japan).
OF DISPERSION
STRENGTHENED
x0
AIN-( Ni, MO or W)
and
contained
random
paltic.lcs
agrermrnt
of cylindrical, bean shaped particles. (‘oordination
DEFORMATION
No
matrix
I :ni\c%r-
(Deakin
non-spherical Good
particle
rcportrd
1000
\:(I1 41.
Mrttrl(.,
madr
powder.
Aluminium
(In Russian.)
of a method is drained
and
Sap
(In .Japanest~.)
material
was
distributions
simulation
for clost~ and
No 11112,
is
alloying
OF NON-
Aust.ralia).
described.
and
~f~)l/.shk”~/,(~,~(~IWnttcllurgiyu.
Powlrr
It
A
for stirred
in a stirrcxd
P.E. Kardnagh
Vol 84. No 3, 1995,
packing shaped
DENSITY
PocPf~Pr
I’ntvcrsity,
). .J. Jc~ptrrt Sec.
.Japan
nori-
PARTICLES
G.T. Nolan
(liokkaido
lIokkaido.
wpr?
valurs
OF HIGH
A.T. Mamadov.
said
PACKING
packittg
surfaces.
METHODS
powder
RANDOM
A
fostrt
are repot-ted.
COMPACTION
size
experitnc~nt~ally
which
lvhich
and
simulated.
was tr5tcd
sit?/, &toria.
This
stresses
forces
cleaning
density
sc~l:onds.
shear
frictional
and
properties
to
to hot bi-
SYSTEM
significant
is proposed
wet-r
of
Al
drnsification
NITRIDE-METALS
of
are ronsidrrcd.
particlc
10 pm
are
stirrrd
thr,sc
model
SPHERICAL
It is reported
I Lttivcrsi1y
grinding
thtarc
and
and
below SM.
ALUMINIUM
with respc>c,t to ball milling and it
brtwc~en
size, energy
METALLURGY
BALL
A,wdw Twh r/r,/..
ultrafine
that
different-rs
BI-DIMENSIONAL
SIZE
(I,uIea
is disc-ttssrd of conventional
stirrrd POWDER
of
along
GRADIENl
IN THE
pressing
1’0184, No 2, 1095. 101.lOti. powders tnodels
c*ellular tnicrogratns.
glide
sinterirtg with no grain growth. and gradient arc drscrihrtl.
Simulation
columnat
intt n-hrrca
In-edorninaic,s
MATERIALS
on a
FOR A STIRRED
I>ulra, Swcbdcn)
’ hi
Umol
drfortnat
’ for dislocaticln
1994. 639-643.
sintc,ring
validated
OF PRODUCT
1;. Forssbcrg
Tcchnol..
speed
botindaric5.
graded
DISTRIBUTIONS MILL
of 2X-700
arc
grain
been
M. Gdo,
size and
slip mcchattism
326 liJ.tnol
pot-o,
Hua
Int. .J. I%U-
Taiwan).
a dislocation
K. Atarashiya
with
r-dngrb of‘ nratrrials. K.E’. Shut
at 340
high
Al-
Aclivatiort
fack)r
vary
Poisson’s
of ~omprtitiott
arc’ calculated
FUNCTIONALLY
incorporate
It is shown that described I,>, two
intensification
of ceramics
nieasurc
iott was
01 stntrretl
dt~scribt~d.
yield fttnct.ion to
ratio
and
forging
consolidat
effects. can bc
parameters, tnaterial
CENTRIFUGAL
of powder
at-r
temperature and
7Yrtu.s. A, \‘ol %A, No 8. 1995. 203 l-%)51.
the need untreated
implant,ation
of dt~formation
Xvol’lc,Al:,(!, c~nergies
R.E.
t reatmettt
btam
Studies
OF
POWDERS
J ,Wc~tccIs,Vool 47,
No 4, 199.5, ‘O-26. tnodif;v surfaces
HOT CONSOLIDATION
AND CERAMIC
extruded strengths
made with
rate of
of about
Al- (2
t,o
of raJ,idly by gas
solidified
atomization,
“,,(:r attcl cooling 103deg,src :%‘:,(‘r 4)‘!,(‘r
rate.
gave in had
Al.
a llot
tc>nsilcl
of 21iW:WJ MPa.
MPR March 1996 37
PROCESSING
Fundamentals OF POWDERS
MODELLING METAL
11.1~.Mullet-, W.J. Ensinger. Ion
‘of powders
is rcvie~rvrd with
to
regard
to
Dutton
Force
ct
Rase,
al.
Ohio.
(Wright-Patterson
Air
Melnl(.
Matrr.
ITSA)
to agitate surfaces
the powder to expose t,) the ion beam.
conducted
using
a continuum
Methods.
including
ion
and
rultb
modified
ion
assisted
Results,
deposition,
concerning
annealing, discussed.
art>
and
dcscribrd.
tadiation
doping and Some examples
Modclling flow
tnicrostructurc consolidation
damage,
properties. arc given.
are
and
ATOMIZATION/
a stress
Poisson‘s
SUBSTRATE
QUENCHING
SOLIDIFIED
POWDERS
OF RAPIDLY
and
which
depend
crrrp.
The
ct
llniversity. rlvr
(Nattonal Tsing
al.
llsinchu.
MPttrli.,
31. No 2, 1995,
Vol
145-153.
(‘cnt.rifugal atomizal iott and substrate quenching have he6.n combined for production
of flaky
of process
paramrtcrs
struc’turt~
arc described.
30 pm thick are
with
reportt~d.
grains
with
powders
of Al. Effects
on particle Particle
aspcc?
sizes of lo-
ratios
St.ruc~tures
on density.
In sintrt
ratio
tW\*ceen
tnotit~l was
PREDICTION
gi\,es
a
is
Pressing
suggcstcd
COMPRESSION
IN
milling
milling.
.Joslin,
K.1I.G.
Birmingham, Mater.
Asttbcc
(l’nivrrsity
Hirtninghanl.
75x,/s.
A, i-1,1 26.4.
No
01
Mrtcrlf.
IlKi).
5,
19%.
1087-1091. that
or Al alloy powders dimensional time
is
to
to large
Full
are suh,jrctcd
reduced
abrasion
encapsulated
c~omprcssiotr,
attributed lead
when
high
of particle
and
Itigh
is
ARTICLES
mclchanical
USING
GAS DRAINAGE
1994,
Development in which gas during
plasticisers t.o
computer
are ensure
Ijensitirs for Fc hasp
l-6.
pressing used.
is
tafficient
of 7.4-7.7 materials.
of compaction frotn a metal reported.
A porous gas
gm.c’m ” are
The
model mill.
of
betwrcbn
predicted of parking
Pow&r
T~l??rt~f.,
199-205. of
is
ENERGIES
is
and density
is
rt~ported
taxpcrimrntal for random
orirntat.ions
close
and nail rtumbcrs
wcxrc drt,rrmined
loosc~ parking.
a
(i.
compositionally
front
ultrafint,
two-step
has
ltowdrrs
sintcring.
tq
at
fclrmrd
STRUCTURAL
EVOLUTION
MECHANICAL
ALLOYING
ALUMNIUM-IRON
Sttx(?ural
600
during
Properties
DURING OF
POWDERS
c\olution
of Al-(1,
increased O.O25at%
t,hc
reduction.
A1-%5%Fc
M. l!%esterc,i (t.:st,av Materialoveho Slovakia)
Pokrok,t~
Al
crystallinr
rat<,
of
was
ratio
ltarticlr
fully
sizcx
amorphous
and Al-lO.‘i”,,Fe
was a mixturt,
and amorphous in all alloys
phases. F’(tAIzj formt,d excrpt Al-2.5’:5Ft~ which
Ftl,Alr,
consolidated rrtnainrd
after
10.7%
of cystallinrB
rntlling.
and
25’:&
Shock powders
nano-ctystallirtt~.
MICROSTRUCTURES
OF ATOMIZED
ALUMINIUM-CHROMIUM
POWDERS
ANDPROPERTIESOFEXTRUDED POWDERS Kobayashi
et
al.
(Osaka
l:rtivrrstty,
Z. M~tnlbkd. Vol X6, No 4. 19!)5,
powders,
cooling
solubility SAV, Kosice.
in
in the ball to powder
accclcrated
A
M. k&d,
“,,Fc
Fe
in t.hta as-niillr,d
Incrclase
were correlated
Vyskumu
of
from the rqriilibrtum value 01 up to 4.4’:,. Nanometer grains
prcscttt
AI-Cr
ALUMINIUM
mechaniaxl
Solubility
2x9-292. The microstructures ACTIVATION
during
4. 7.13, 10.7 or 26)at
investigated.
K.F.
removal. claimed
that
(’ tn N. AlN was
Japan).
OF DISPERSION
STRENGTHENED
x0
AIN-( Ni, MO or W)
and
contained
random
paltic.lcs
agrermrnt
of cylindrical, bean shaped particles. (‘oordination
DEFORMATION
No
matrix
I :ni\c%r-
(Deakin
non-spherical Good
particle
rcportrd
1000
\:(I1 41.
Mrttrl(.,
madr
powder.
Aluminium
(In Russian.)
of a method is drained
and
Sap
(In .Japanest~.)
material
was
distributions
simulation
for clost~ and
No 11112,
is
alloying
OF NON-
Aust.ralia).
described.
and
~f~)l/.shk”~/,(~,~(~IWnttcllurgiyu.
Powlrr
It
A
for stirred
in a stirrcxd
P.E. Kardnagh
Vol 84. No 3, 1995,
packing shaped
DENSITY
PocPf~Pr
I’ntvcrsity,
). .J. Jc~ptrrt Sec.
.Japan
nori-
PARTICLES
G.T. Nolan
(liokkaido
lIokkaido.
wpr?
valurs
OF HIGH
A.T. Mamadov.
said
PACKING
packittg
surfaces.
METHODS
powder
RANDOM
A
fostrt
are repot-ted.
COMPACTION
size
experitnc~nt~ally
which
lvhich
and
simulated.
was tr5tcd
sit?/, &toria.
This
stresses
forces
cleaning
density
sc~l:onds.
shear
frictional
and
properties
to
to hot bi-
SYSTEM
significant
is proposed
wet-r
of
Al
drnsification
NITRIDE-METALS
of
are ronsidrrcd.
particlc
10 pm
are
stirrrd
thr,sc
model
SPHERICAL
It is reported
I Lttivcrsi1y
grinding
thtarc
and
and
below SM.
ALUMINIUM
with respc>c,t to ball milling and it
brtwc~en
size, energy
METALLURGY
BALL
A,wdw Twh r/r,/..
ultrafine
that
different-rs
BI-DIMENSIONAL
SIZE
(I,uIea
is disc-ttssrd of conventional
stirrrd POWDER
of
along
GRADIENl
IN THE
pressing
1’0184, No 2, 1095. 101.lOti. powders tnodels
c*ellular tnicrogratns.
glide
sinterirtg with no grain growth. and gradient arc drscrihrtl.
Simulation
columnat
intt n-hrrca
In-edorninaic,s
MATERIALS
on a
FOR A STIRRED
I>ulra, Swcbdcn)
’ hi
Umol
drfortnat
’ for dislocaticln
1994. 639-643.
sintc,ring
validated
OF PRODUCT
1;. Forssbcrg
Tcchnol..
speed
botindaric5.
graded
DISTRIBUTIONS MILL
of 2X-700
arc
grain
been
M. Gdo,
size and
slip mcchattism
326 liJ.tnol
pot-o,
Hua
Int. .J. I%U-
Taiwan).
a dislocation
K. Atarashiya
with
r-dngrb of‘ nratrrials. K.E’. Shut
at 340
high
Al-
Aclivatiort
fack)r
vary
Poisson’s
of ~omprtitiott
arc’ calculated
FUNCTIONALLY
incorporate
It is shown that described I,>, two
intensification
of ceramics
nieasurc
iott was
01 stntrretl
dt~scribt~d.
yield fttnct.ion to
ratio
and
forging
consolidat
effects. can bc
parameters, tnaterial
CENTRIFUGAL
of powder
at-r
temperature and
7Yrtu.s. A, \‘ol %A, No 8. 1995. 203 l-%)51.
the need untreated
implant,ation
of dt~formation
Xvol’lc,Al:,(!, c~nergies
R.E.
t reatmettt
btam
Studies
OF
POWDERS
J ,Wc~tccIs,Vool 47,
No 4, 199.5, ‘O-26. tnodif;v surfaces
HOT CONSOLIDATION
AND CERAMIC
extruded strengths
made with
rate of
of about
Al- (2
t,o
of raJ,idly by gas
solidified
atomization,
“,,(:r attcl cooling 103deg,src :%‘:,(‘r 4)‘!,(‘r
rate.
gave in had
Al.
a llot
tc>nsilcl
of 21iW:WJ MPa.
MPR March 1996 37