Post on 06-Feb-2018
COMPUTATIONAL ANALYSIS AND COMPUTATIONAL ANALYSIS AND DESIGN OF SINGLE SCREW DESIGN OF SINGLE SCREW
EXTRUDERS HAVING SCREWS OF EXTRUDERS HAVING SCREWS OF COMPLEX GEOMETRY WITH MIXING COMPLEX GEOMETRY WITH MIXING
ELEMENTSELEMENTS
SPE EUROTEC 2011SPE EUROTEC 2011
BARCELONA, SPAINBARCELONA, SPAIN
John VlachopoulosJohn VlachopoulosMcMaster University McMaster University
Nick PolychronopoulosNick Polychronopoulos **Polydynamics, Inc.Polydynamics, Inc.
Shinichiro TanifujiShinichiro TanifujiHyper Advanced Simulation Laboratory (H.A.S.L.) Hyper Advanced Simulation Laboratory (H.A.S.L.)
The The ““heartheart”” of every extruder is an of every extruder is an
ARCHIMEDEAN SCREW attributed to ARCHIMEDEAN SCREW attributed to
Archimedes 287Archimedes 287--212 BC but, actually 212 BC but, actually
known to Egyptians for irrigation in the Nile known to Egyptians for irrigation in the Nile
Delta and the auger (screw drill) for Delta and the auger (screw drill) for
carpentry was known to the Greeks beforecarpentry was known to the Greeks before
the 3rd Century BC.the 3rd Century BC.
See:See:
Chris Rorres, J.Hydraul.Eng., Vol.126, 71Chris Rorres, J.Hydraul.Eng., Vol.126, 71--80, 80,
(January 2000)(January 2000)
SINGLE SCREW EXTRUDER:SINGLE SCREW EXTRUDER:
Rotating screw in a heated barrel.Rotating screw in a heated barrel.
Early developments for rubber Early developments for rubber
due to Thomas Hancock in 1820 indue to Thomas Hancock in 1820 in
England.England.
Modern developments started in Modern developments started in
the 1950the 1950’’s.s.
MODELING of EXTRUSION MODELING of EXTRUSION started in the started in the
19501950’’ss
Prominent names Prominent names
at DUPONT (USA)at DUPONT (USA)
oo McKelveyMcKelvey
oo GoreGore
oo SquiresSquires
19501950’’ss
oo Maillefer (parallel Maillefer (parallel
developments in developments in
Switzerland, 1950Switzerland, 1950’’s)s)
-- Maddock (Union Carbide) 1950Maddock (Union Carbide) 1950’’ss-- McKelveyMcKelvey’’s book on P.P. appeared in 1962s book on P.P. appeared in 1962
-- The book by Z. Tadmor and I. Klein appeared in The book by Z. Tadmor and I. Klein appeared in
19701970
MODELING OF EXTRUSION IS 60 YEARS MODELING OF EXTRUSION IS 60 YEARS
OLD, BUT MANY CHALLENGES REMAINOLD, BUT MANY CHALLENGES REMAIN
SINGLE SCREW EXTRUSION IS THE MOST SINGLE SCREW EXTRUSION IS THE MOST
COSTCOST--EFFECTIVE WAY TO MELT AND PUMP A EFFECTIVE WAY TO MELT AND PUMP A
POLYMER POLYMER
SCREW DESIGN calls forSCREW DESIGN calls for
-- OUTPUT MAXIMIZATIONOUTPUT MAXIMIZATION
-- MELT TEMPERATURE MINIMIZATIONMELT TEMPERATURE MINIMIZATION
-- EXTRUSION STABILITYEXTRUSION STABILITY
-- MELT QUALITYMELT QUALITY
OPTIONS:OPTIONS:
-- CONVENTIONAL single flighted screwsCONVENTIONAL single flighted screws
-- BARRIER screwsBARRIER screws
-- Screws with MIXING SECTIONSScrews with MIXING SECTIONS
Conventional single screw (also Conventional single screw (also
called: plasticating) extruders arecalled: plasticating) extruders are
composed of three sections:composed of three sections:
In all screws at In all screws at leastleast the first 70% or so of the first 70% or so of
melting is due to the shear stress in the melting is due to the shear stress in the
melt film between the barrel and the solid melt film between the barrel and the solid
bed surface. bed surface.
BARRIER SCREW PRINCIPLEBARRIER SCREW PRINCIPLE
-- Increased melting.Increased melting.
-- At least 80% is melted by At least 80% is melted by shearshear over over
the solid bed (i.e. very little conductive the solid bed (i.e. very little conductive
melting).melting).
MADDOCK (Union Carbide) MADDOCK (Union Carbide)
MIXING SECTIONMIXING SECTION
�� SOLID PARTICLES TRANSPORTSOLID PARTICLES TRANSPORT
(pellets, size, properties, powders, (pellets, size, properties, powders,
difficult to describe mathematically difficult to describe mathematically
particle flow)particle flow)
�� MELTING OF THE PACKED BED OF SOLID MELTING OF THE PACKED BED OF SOLID
PARTICLESPARTICLES
(how do solid particle properties affect (how do solid particle properties affect
the melting rate?)the melting rate?)
�� COMPLEX SCREW GEOMETRYCOMPLEX SCREW GEOMETRY
(barrier screws, screws with various (barrier screws, screws with various
types of mixing elements)types of mixing elements)
CHALLENGES:CHALLENGES:
Our present modeling approachOur present modeling approach
MODULAR, EASY TO UPGRADE MODELS FOR EACH SECTION
Current focus
DARNELL AND MOL (1956) MODELDARNELL AND MOL (1956) MODEL
BALANCE OF BALANCE OF FORCESFORCES AND AND TORQUESTORQUES
MELTING (TadmorMELTING (Tadmor’’s Model)s Model)In the late 50In the late 50’’s, Bruce Maddock did experiments, s, Bruce Maddock did experiments,
pulling the screw and examining what happened. pulling the screw and examining what happened.
The conclusion was that MELTING REALLY OCCURS The conclusion was that MELTING REALLY OCCURS
IN A FILM BETWEEN BARREL AND SOLID BED. A IN A FILM BETWEEN BARREL AND SOLID BED. A
MELT POOL FORMS IN FRONT OF THE REAR MELT POOL FORMS IN FRONT OF THE REAR
FLIGHT, as shown: FLIGHT, as shown:
Metering section:Metering section:
We decided to use the We decided to use the Hele Hele –– Shaw Shaw
flow approximation layer flow approximation layer –– by by –– layerlayer
2.5D analysis with 3D geometry2.5D analysis with 3D geometry
Because our objective is screw design Because our objective is screw design
which means, simulation for a starting which means, simulation for a starting
geometry, geometry upgradegeometry, geometry upgrade……..till ..till
satisfactory results obtained. satisfactory results obtained.
50 or more runs maybe need.50 or more runs maybe need.
““trial trial –– and and –– error on the computer error on the computer
screenscreen””..
�� HELE HELE –– SHAW FLOW APPROXIMATIONSHAW FLOW APPROXIMATION
�� 33--D NAVIER D NAVIER –– STOKES for creepingSTOKES for creeping
non non –– Newtonian flowNewtonian flow=
⋅∇+−∇= τP0
∂∂
+∂∂=
i
j
j
iij x
V
x
Ve
2
1 )( ijij ef=τ 3,2,1, =ji
VTkTVC P ∇+∇=∇⋅=
:2 τρENERGY:ENERGY:
0=
∂∂
∂∂+
∂∂
∂∂
y
PS
yx
PS
x( ) ( )∫=
h
o zyx
duzyxS
,,,
2
η
x
P
h
SVx ∂
∂−=y
P
h
SVy ∂
∂−= ( ) ( )∫ ′′′
∂∂−=
h
x z
zdz
x
PzV
0 η( ) ( )∫ ′′′
∂∂−=
h
y z
zdz
y
PzV
0 η
0=⋅∇ V
VTkTVC P ∇+∇=∇⋅=
:2 τρENERGY:ENERGY: 3D3D
COMPRESSIONCOMPRESSION METERINGMETERINGFEEDFEED
BarrelBarrel Diameter = 40 mmDiameter = 40 mm
5D5D 10D10D
PLABOR JAPAN EXPERIMENTSPLABOR JAPAN EXPERIMENTS
�� give measured value of pressure at give measured value of pressure at both ends as boundary condition.both ends as boundary condition.
�� predict pressure distribution / predict pressure distribution / temperature distribution / extruder temperature distribution / extruder outputoutput
MaterialMaterial::::::::LDPE, PowerLDPE, Power--law approximationlaw approximation
12D12D
McMaster University ExperimentsMcMaster University Experiments-- Single flighted screw, no mixing element Single flighted screw, no mixing element
-- D=38 mm, L/D=24D=38 mm, L/D=24
Material: HDPE (80 RPM)Material: HDPE (80 RPM)
•• FLOW RATEFLOW RATE
-- Measured: 13.34 kg/hrMeasured: 13.34 kg/hr
-- Predicted: 13.67 kg/hrPredicted: 13.67 kg/hr
•• PEAK PRESSUREPEAK PRESSURE
-- Measured: 29.75 MPaMeasured: 29.75 MPa
-- Predicted: 27.21 MPaPredicted: 27.21 MPa
Somewhat better results for LDPESomewhat better results for LDPE----------------------------
-- L/D=30, Diameter (D)= 88.9mmL/D=30, Diameter (D)= 88.9mm
-- 4 different screw designs4 different screw designs
-- LDPE MI 0.3LDPE MI 0.3
-- LLDPE MI 1 LLDPE MI 1
BRAMPTON ENGINEERING/McMASTERBRAMPTON ENGINEERING/McMASTER
UNIVERSITY EXPERIMENTS CANADAUNIVERSITY EXPERIMENTS CANADA
Experimental conditionsExperimental conditions
•• 16 runs performed: 4 screws 16 runs performed: 4 screws x x 22
polymers polymers x x 2 output rates2 output rates
•• Pressures measured at 8 locationsPressures measured at 8 locations
along screw, plus at end of screwalong screw, plus at end of screw
-- values recorded once per secondvalues recorded once per second
•• Melt temperature measured atMelt temperature measured at
end of screw end of screw
L/D=30, Diameter (D)= 88.9mmL/D=30, Diameter (D)= 88.9mm
Barrier screw with MaddockBarrier screw with Maddock
Measurement
Simulation
Lagrangian melting particle simulationLagrangian melting particle simulation
(Diameter of the initial solid particles: 5 mm)(Diameter of the initial solid particles: 5 mm)
HDPEHDPE
Lagrangian melting particle simulationLagrangian melting particle simulation
(Diameter of the initial solid particles: 5 mm)(Diameter of the initial solid particles: 5 mm)
HDPEHDPE
Lagrangian melting particle simulationLagrangian melting particle simulation
(Diameter of the initial solid particles: 2.5 mm)(Diameter of the initial solid particles: 2.5 mm)
HDPEHDPE
Lagrangian melting particle simulationLagrangian melting particle simulation
(Diameter of the initial solid particles: 2.5 mm)(Diameter of the initial solid particles: 2.5 mm)
HDPEHDPE
THANKSTHANKS
Q & AQ & A