In A123 Systems, CAE/FEA tools are widely used to improve the efficiency of the design on battery packs and modules. A123 engineers utilize Altair’s HyperWork Suite for structural FEA including linear and nonlinear statics analysis, modal frequency and random vibration analysis, as well as nonlinear dynamic analysis such as mechanical shock and drop test analysis.
Two examples are presented in this presentation. The first example is a systematic approach to simplify and accurately model complex prismatic battery modules for vibration FEA. The second example presented is an approach to utilize Altair’s partner program DesignLife to conduct durability analysis.
Modeling and Analysis of the Battery Packs and Modules in A123 Systems
1. Modeling and Analysis of the Battery
Packs and Modules in A123 Systems
Binshan Ye & Shawn Zhang
A123 Systems, Inc.
2. Outline
• Overview of CAE capacity in A123
• CAE Modeling and Analysis Examples
• Random vibration fatigue analysis with HWPA program (DesignLife)
• Cell material properties characterizing with HyperStudy
• Concluding Remarks
3. A123 Engineering Simulation Capability
A123 Systems
Engineering Simulation
CFD and Thermal Management Battery Life Analysis Finite Element Analysis
Cooling Concept Linear Statics and
Battery Life Estimation
Development and Modal Frequency
Software Development
Validation
Random Vibration and
Module and Pack Level Fatigue
Thermal and Flow Analysis Battery Life Analysis
Mechanical Shock and
Thermal/Electrical Battery Electrical Drop Analysis
Coupling (Joule Heating) Performance Simulation
Nonlinear Statics
Thermal Analysis for
Electronics
Cell R&D and
External Supplier
4. Pack and Module Level FEA Analysis
• Linear Statics and modal frequency analysis
• Modal frequency analysis
• Foot/knee load, handle load, and lifting assistance analysis
• Topology/topography/shape/gauge optimization
• Random vibration stress and fatigue analysis
• RMS stress calculation
• Fatigue life calculation for metal parts
• Mechanical shock, pothole, and drop analysis
• Nonlinear and contact analysis
• Snap-in/pull-out force estimation
• Jack loading analysis
• Bolt assembly, module pressure plate, etc.
5. FEA Tools Used in A123 Systems
• Altair HyperWorks Suite
• Radioss/Bulk
• Radioss/Block
• OptiStruct
• HyperStudy
• LS-DYNA3D
• ABAQUS (Implicit/Explicit)
• Access to other software through HyperWorks Partner Alliance License
• nCode DesignLife
• Key to Metals
• Others
• Altair PBS Pro
7. Battery Pack Vibration Analysis
• A123 conducts random vibration stress and fatigue analysis according
to customer specifications or industrial standards
• Approach
• Use Radioss/Bulk to calculate RMS stresses from the PSD profiles
• Estimate fatigue life using nCode DesignLife if necessary
SAE J2380 PSD Profiles
8. Example – Random Vibration Analysis
• A prototype battery pack had a test failure on mounting brackets during
random vibration test
• The analysis team was involved to identify the root causes of the
failures and find the solution in a limited time frame
9. Challenges
• A few locations on mounting brackets showed fatigue cracks
• Initial random vibration stress analysis showed the failure locations
have high RMS stress during vibration events, but it cannot
accurately quantify the fatigue life
• The fatigue properties for the metal components were unknown
• Project timing and budget won’t allow performing material test to
obtain the fatigue properties
10. Correlating the Fatigue Properties
• nCode DesignLife was used to evaluate the fatigue life of metal
components:
• The stress-life properties were estimated in DesignLife based on material specs
• Random vibration fatigue engine was used to estimate the fatigue life of the metal
components
• The fatigue properties and analysis parameters were then adjusted to correlate
the analysis results with test results
Material Stress Life Curve
Vibration Fatigue Analysis Engine
11. Result Comparisons
• With correlated fatigue properties, the analysis identified all test failure
locations:
• The failure locations have relatively high RMS stresses comparing to material specs
• The fatigue lives in these locations are lower than the requirement
90% of required life 10% of required life
3 RMS stress : 55% of material σuts 3 RMS stress: 72% of material σuts
Fatigue life: 90% of the required life Fatigue life: 10% of required life
12. Improve the Design Through Analysis
• Based on the analysis results, new design concepts were proposed:
• Change the shape of the components
• Add reinforcement brackets
• Change welding patterns
• New pack design passed the random vibration fatigue analysis
• These design changes were implemented and the new pack went
through random vibration test without fatigue issue
Infinite 65 lives
14. Challenges for Battery Module Modeling
• Modal frequency is critical for battery
pack design, and battery modules
play a significant role
• Cell property largely unknown
• Ideally, we would like to use a simple
homogenized model to represent the
complex structure of the module
(cells, heat sinks, and bands)
• The first few modal frequencies of the
module model should meet the test
results
15. Two Module Modeling Approaches
• Homogenized model • Detailed model
• Cell, heat sink, compliance pad are • Each component is modeled in detail with
homogenized into blocks corresponding material properties
• End plate is modeled with shell • End plate is modeled in detail with shell
elements as one plane sheet elements
• Module bolt is modeled with beam • Module bolt is modeled with beam
elements elements
• All materials are isotropic • Pro and Cons:
• Pros and Cons: • Can better predict module dynamic
• Can be quick modeled and use very behavior
little CPU time • Long modeling time due to complexity of
• Accuracy is compromised due to the module
simplification • High CPU and memory costs
16. Hybrid Module Modeling Approach
Z
Z
X
Y
• Endplate modeled in detail by shell element
• Bolt was modeled by beam element with rod section
• Cell, heat sink, cell compliance pad, band were homogenized into a 3-d
orthotropic material
• Local coordinate system was used for the orthotropic material modeling
17. Characterizing the Material
• Three modules were tested with free-free and fixed BC
• Large size module, medium size module, and small size module
• For free-free boundary condition, the first 3 modes from test were used
for FEA model correlation
• For fixed boundary condition, the first 5 modes from test were used in
FEA model correlation
• Homogenized orthotropic material was formulated using the following
engineering constants
18. Characterizing the Material
• Goal was to adjust E1, E2, E3, G12, G13, G23 to correlate both the
mode shapes and frequencies with test results.
• Observations during initial evaluation:
• Some Eii, Gij, and vij have strong influence to long and medium size modules’
modal frequencies;
• Other Eii, Gij, and vij have significant effect to small module modal frequencies
• The remaining Eii, Gij, and vij have little effect to the first 3 modal frequencies at
all. In that case, they are assigned to zero, leading to a simple material matrix
• Material parameters were first manually adjusted to match modal
shapes in order.
• Then HyperStudy was used to match first 3 frequencies more closely
24. Summary of Hybrid Module Model
• This hybrid module model was a compromise among all 3 size modules,
with deviation within 5% in free-free boundary condition
• The hybrid module model was more skewed to large size modules
because for small size modules, the first frequency is very high already,
making them less sensitive to external vibration.
• By using such approach, a battery module for pack analysis can be
quickly modeled and still achieve good analytical results
25. Concluding Remarks
• A123 has a broad range of engineering simulation capabilities to
support battery pack/module development activities
• Altair’s HyperWorks Suite and HWPA are the best cost-effective tools to
match A123’s FEA simulation requirements