simulating wear in disc brakes - comsol multiphysics® · disc brake wear analysis • effect of...
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Simulating Wear in Disc Brakes
Veryst Engineering 47A Kearney Road Needham, Massachusetts 02494 phone 781.433.0433 [email protected] www.veryst.com
Nagi H. Elabbasi, Matthew J. Hancock, and Stuart B. Brown Veryst Engineering, Massachusetts
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About Wear
• Wear is the process of gradual removal of material from solid surfaces subject to sliding contact
• Rate of wear depends on properties of contacting surfaces and operating conditions
• Archard’s equation is simple but widely used
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Volume of material removed
N TKF LWH
=
Normal force Sliding distance
Hardness
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About Wear
• We used a modified version of Archard’s equation
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Wear constant (Pa-1) Contact pressure
Magnitude of sliding velocity
Wear rate (m/s)
N Tw k p v=
Wear constant k can be a function of material properties, surface properties and temperature
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Wear Implementation
• Wear equations not directly available in FEA codes
• Straightforward to implement in COMSOL Multiphysics as Boundary Ordinary Differential Equation (ODE) defined on the contact surfaces
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Wear Implementation
• Modify the gap calculation in the contact conditions to account for wear
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g
λ
g
λ
0,0 w
000
=≥≥
λλg
g
0)(0
0
=+≥
≥+
λλ
wg
wg
Note: g is the gap, λ is the contact pressure
No contact (g>0, λ=0)
In contact (g=0, λ>0)
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Wear Implementation
• Advantages of this wear modeling approach – Simple to implement – Does not require “structural” changes in FEA
calculations – Fast solution times
• Disadvantages of this approach – Only valid for small values of wear depth
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Section of disc
Pin
Apply pressure
Move disc
Pin-on-Disc Validation Model
• Pin-on-disc wear test
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Pin-on-Disc Validation Model
• Wear depth
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• Total wear volume (integration of wear depth over pin surface) in agreement with theoretical prediction
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Pin-on-Disc Validation Model
• Contact pressure evolution
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• Wear decreases maximum contact pressure and increases contact area
• Wear model failing at 200 seconds
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Disc Brake Wear Analysis
• Model includes brake disc, brake pads and backing plates
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Brake pads
Brake disc/rotor
Backing plate
Caliper not included in model
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Disc Brake Wear Analysis
• Rotation of brake disc is not explicitly modeled – The intent is to ignore transients in structural
analysis and focus on the steady-state solution – Including disc rotation requires a much smaller
time step and longer solution times
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Disc Brake Wear Analysis
• Effect of disc rotation included in four parts – As a convective term in the heat transfer analysis
– In the velocity calculation for friction heat generation
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( )p EXC T k T Qρ ⋅∇ = ∇ ⋅ ∇ +v
( )F T EX F EXq = ⋅ + ⋅f v v f v
Slip velocity resulting from FEA nodal displacements
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Disc Brake Wear Analysis
• Effect of disc rotation included in four parts – In the calculation of friction conditions
• Reasonable to assume constant state of slipping friction with slip velocity equal to vEX
– In the wear equation • Reasonable to assume that only vEX contributes to wear
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Sources of Multiphysics Coupling
• Frictional heat generation • Thermal expansion • Thermal contact • Wear evolution equation
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Analysis Case 1
• Continuous braking pressure of 0.2 MPa applied to backing plates – Relatively soft brake pressure typical of a long steep
downhill drive – Results similar to a more aggressive intermittent braking
pattern – Weak stabilization spring added to help with convergence
before contact is established
• Braking time = 3 minutes
• Vehicle speed = 54 km/h
• Pad modulus = 0.25 GPa 15
• Friction = 0.3
• Wear constant = 0.5x10-13
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Case 1 Results: Contact Pressure
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At initial contact After 1 minute
Contact pressure (MPa) Contact pressure (MPa)
• Contact pressure initially concentrated at the leading edge of the pad (due to friction)
• Contact pressure gradually spreads out over wider area due to wear
Direction of rotor rotation
Direction of rotor rotation
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Case 1 Results: Contact Pressure
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At 2 minutes Animation
Contact pressure (MPa)
• Contact pressure gradually spreads out over wider area due to wear • Contact pressure higher at inner radius of pad
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Case 1 Results: Wear Depth
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After 5 seconds After 1 minute
Wear depth (μm) Wear depth (μm)
• Wear initially concentrated at the leading edge of the pad • Wear gradually spreads out over wider area of pad
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Case 1 Results: Wear Depth
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After 2 minutes Animation
Wear depth (μm)
• Wear higher at outer radius of pad due to higher sliding velocity
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Case 1 Results: Temperature
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• Initial temperature rise severe in disc
• Steady state temperatures not reached even after 3 minutes
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Case 1 Results: Temperature
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Temperature (oC) Temperature (oC)
After 30 seconds After 3 minutes
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Summary
• Developed a wear model in COMSOL – Boundary ODE representing wear rate equation – Wear depth modifies contact gap condition
• Validated model with pin-on-disc problem • Simulated wear in automotive disc brakes
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