Copyright 2003 Hitachi Global Storage Technologies
The oil-air interface problem offluid dynamic bearings in
hard disk drives
Ferdi Hendriks
Presented at MPI 2005,WPI, Worcester, MA
June 13-17, 2005
Copyright 2003 Hitachi Global Storage Technologies
Introduction to FDBs for HDDs
• Fluid bearings have several advantages over ball bearings in spindles for modern hard disk drives.– Quietness– Very low non-repeatable runout– Shock resistance
• Well known issues are:– Oil-air interface instability (Asada et al.)– Bubble ingestion (Asada et al.)– Leakage (Muijderman, Bootsma, Tielemans)
• They used a homogenized Reynolds eqn (8 = infinity)– Numerical simulation of free boundary problem
Copyright 2003 Hitachi Global Storage Technologies
7 m
oil
oil
FDB of “stationary shaft design”
FDB’s3 m
N.V. Philips:
Evert Muijderman
Jan Bootsma
J. Tielemans
Ultracentrifuges 60 krpm,
Later HDDs
?Stefan Risse
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Oil shuttle motion
OAI-NON-OP
OAI-OPherringbone
grooves
spiralgrooves
oil-air interface
OAI-NON-OPOP = rotating; NOP = stand still
OAI-OP
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FDB’sPressure distribution in Hitachi’s microdrive
Rotor (smooth)
Stator (grooved)
rotor
stator
FDB of rotating shaft designCa. 1 million cells
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Last year’s problem – MPI 2004
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Capillary Couette flow with constant gap – is it stable?
0
1
: / (1)
: 90
oil air
V hReynolds no : Re
Capillary no Ca V O
Wetting angle
neglect gravity (Bond number)
neglect flow field in the air ( )
ρµ
µ σ
γ
µ µ
= <<
=
<
>>
1R
h
γ
solid walls
12V−
1R
12V 3 3
1 2
12 12
12
:
1 1
h hU h p h pt x x x z z
BC
p and tangential stress conditionR R
ρ ρ ρ ρµ µ
σΓ
∂ ∂ ∂ ∂ ∂ ∂+ = + ∂ ∂ ∂ ∂ ∂ ∂
= +
h
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Average OAI deflection in a land-groove geometry with symmetry
oil
periodic
Oil/air interface
oil
air
symmetry
periodic
moving wall
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State of the problem after 1 yr
• We know that capillary interfaces in land-groove geometries tend to form fingers in the grooves. The oil film rises over land regions.
• We know that the number of grooves plays a crucial role in oil-air interface deflection (analytical result)
• We do not know the stability as a function of Ca, Re and groove parameters: land/groove ratio and groove depth/clearance ratio.
• We know that averaging of the capillary interface across the fluid film is not (really) allowed. This is especially true in the grooves. I.e. There is no such thing as “the interface deflection.”
Copyright 2003 Hitachi Global Storage Technologies
Oil film on rotor / Capillary Taylor- Couette flow
average interface (MPI 2004)
Re = 0
statorrotor
interface shape in the groove
Copyright 2003 Hitachi Global Storage Technologies
MPI 2005 questions
• Describe the capillary interface in a land-groove flow field. Relax (or drop) the averaging assumption.
• Investigate the stability of capillary Taylor-Couette flow– Use average interface; – Eccentric, if the centric case is trivial.
• Does one need to know the flow near the capillary interface to predict when bubble ingestion occurs?
• Does one need to know the detailed flow near the capillary interface to compute loads and torque of the bearing with “engineering precision”
Copyright 2003 Hitachi Global Storage Technologies
Intermag presentation
Copyright 2003 Hitachi Global Storage Technologies
Main observation
• Current HDDs use self-acting spiral groove and herringbone fluid dynamic bearings (FDBs) to achieve precise rotation of a disk pack.
• In some FDB (“self-sealing”) designs oil-air interfaces occur.
• Oil-air interfaces become unstable under certain high stress conditions, expressed by
– The Capillary number viscous stress / capillary pressure– The Reynolds number inertial stress / viscous stress– The fractional eccentricity eccentricity / clearance
• Reynolds eqn with Half-Sommerfeld (Gümbel) or Reynolds BCs is not satisfactory to describe the oil / interface dynamics: Oil is not conserved.
• Modified “true cavitation” approaches are also problematic.
Copyright 2003 Hitachi Global Storage Technologies
Bootsma and Tielemans’ work
• In 1977 Bootsma and Tielemans already suggested thatthe stability of the oil-air interface involves the Capillary number and the Weber Number. Because
We = Ca Re (we care!)
this is equivalent to involvement of the Reynolds number
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Fluid bearing with stationary shaft
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Lower spool of the bearing of stationary shaft design
The oil-air interface (OAI) is located among the rotating herringbone grooves.
We wish to determine its evolution
Z( ,t)
This is a CAD model of the liquid! Not the solid.
Copyright 2003 Hitachi Global Storage Technologies
Groove-fixed (rotating) coordinate system
: ( ):
( , ) :
,,
ir inner shaft radiusd clearancef z groove profile
we do not consider eccentricityrather we are focused on thedetails of a single land/groovepair
θ
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Continuity / Navier-Stokes / Interface
2 2
. 0 (1)
ˆ ˆ2 (2)D
p rD t
ρ µ ρ ρ
∇ =
= −∇ + ∇ − Ω × − Ω
*
*
* * *
u
uu k u r .
*
0 (3 )
ˆ ˆ ( 4 )ˆ ˆ . (5 )
Zt
pσ κ
∂− =
∂= −
×
*
** *
*
u . n
n . T . n
n . T n = 0
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Reynolds’ eqn / compact OAI
3 36 0 (6)p pf f fz zθ θ
∂ ∂ ∂ ∂+ + = ∂ ∂ ∂ ∂
Averaging the flow velocity at the interface, we obtain the evolution equation of the interface:
0 (7)zZ Zu ut θ θ
∂ ∂+ − =
∂ ∂
This relies on the existence of a single, compact oil-air interface. The average velocity at the OAI is
21 1 ˆ (8 )1 2 2
f p− ∇ −u = θ
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Oil-air interface evolution eqn.
2 21 0 (9)2 12 12
' :0 ( , )
2
Z f p Z f pt z
B C sp along z Z t andp and Z are periodic in
θ θ
θπ θ
∂ ∂ ∂ ∂− + + = ∂ ∂ ∂ ∂
= =
( ) [ ]( ), 1 sin (10)
Simplify further by considering shallow grooves
z n k zθ δ θ= + −
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Shallow sine groove OAI evolution,result of linearized theory
( )
( ) ( ) ( )
0
2
,2
1 sinh sin cosh cos cos1 cosh
(11)
intZ t Z
n n k k n n k k nn k n
θ θ
θ θ θ
= + −
− + − − +
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Linearized pressure distribution in a shallow, sinusoidally grooved herringbone
( ) ( ), 1 sin
2, 5
f z n k z
k n
θ δ θ= + −
= =
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Herringbone with sinusoidal groove
pressure axial flow ( ) ( ), 1 sin
2, 5, .1
f z n k z
k n
θ δ θ
δ
= + −
= = =
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OAI evolution for a “tanh” groove profile
( ) ( ) , 1 1 tanh2Hf z s n k zθ θ = + + −
land
groove
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BEM problem setup: step groove
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“Fingering” in a step groove profileBEM solution
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Conclusions
• In fluid dynamic bearings of hard disk drives the oil-air interface deforms largely in response to the flow in the bearing interior.Surface tension has a regularizing effect.
• The OAI is drawn down into the grooves and squeezed upward in lands.
• Interfacial fingering develops, possibly leading to tip streaming. The step groove has the strongest fingering tendency.
• According to shallow groove theory the forced interfacial deflections are reduced exponentially as the number of groovesincreases while they are reduced algebraically as the groove angledecreases. This agrees with experiments by Asada.
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