senior design final presentation (fin)
TRANSCRIPT
![Page 1: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/1.jpg)
Heat Sink Design and Optimization
Presented to Dr. Dereje Agonafer
By
ThermaFlow
August 11, 2016
![Page 2: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/2.jpg)
Outline• Introduction• Testing & Simulation• Results• Conclusion
2Erik Jacobs
![Page 3: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/3.jpg)
Introduction• Background• Average Power Usage Effectiveness (PUE)
• Average PUE of 2.9 for U.S. servers in 2013• Power required for cooling is a major concern• Research on how to improve heat sink
performance
• Motivation• Improve heat sink thermal efficiency• Decrease PCH operating temperature
3Erik Jacobs
![Page 4: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/4.jpg)
4Erik Jacobs
PCH Location
Figure 1.2: Extruded Fin Heat Sink Figure 1.3: Inline Circular Pin Heat sink
Figure 1.1: Winterfell 2OU Hybrid Cooling Server
![Page 5: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/5.jpg)
Procedure1. Develop server model2. Incorporate model into ANSYS Icepak3. Experimental testing4. Perform Computational Fluid Dynamics (CFD) simulation5. Compare simulation & experimental results
5Erik Jacobs
![Page 6: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/6.jpg)
Previous work• Solid model built in Solidworks, imported to Icepak• Parameter-based testing• CFD simulations with conformal meshing
6Erik Jacobs
Figure 1.4: Solid model of server Figure 1.5: Area surrounding PCH (Hard drive not shown)
PCH Location
![Page 7: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/7.jpg)
Outline• Introduction
• Testing & Simulation• Results• Conclusion
7Adam McAvene
![Page 8: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/8.jpg)
Experimental testing• Test was run on the Winterfell 2OU hybrid cooling server
8
External radiator fan and bread board
Server Power Supply
Winterfell 2OU Hybrid Cooled Server
Sample Heat sinks and TIM Injector Figure 2.1: Experimental
Test SetupAdam McAvene
![Page 9: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/9.jpg)
Icepak Model
9
Figure 2.2: Isometric View of CAD-constructed CFD model
Figure 2.3: Isometric View of Icepak-native CFD model
Adam McAvene
![Page 10: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/10.jpg)
Meshing
10
• Non-conformal meshing implemented• Reduce “mesh bleeding”• Refine specific object without affecting other areas
• Significantly reduced testing time
Figure 2.4: Example of Conformal mesh of thin objects
Figure 2.5: Example of Non-conformal mesh of thin objectsAdam McAvene
![Page 11: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/11.jpg)
Heat Sink Designs
11
Figure 2.6: Elliptical Pin Heat Sink
Figure 2.8: Hexagonal Pin Heat Sink
Figure 2.7: Square Pin Heat Sink
Figure 2.9: Cross-Cut Fin Heat SinkAdam McAvene
• Manufactured by Alpha Novatech• Proprietary
“Micro-Forging” Process• Al-6063 (Thermal
Conductivity: 209 W/m-K)
![Page 12: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/12.jpg)
Miniature Partitions• 55 x 8 x 1 and 19 x 8 x 1 mm^3• Redirect airflow leaving the heat sink
12
Figure 2.10: Square Pin Heat Sink With Mini Partitions
PCH Located Underneath Heat Sink
Binh Tran
![Page 13: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/13.jpg)
13Binh Tran
Without Mini Partitions
13
• Flow leaves from gaps between square pins• Air does not travel (and convect) through entire length of heat sink
Figure 2.11: Cross-Sections of Heat Sink/PCH Temperature Without Partitions
![Page 14: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/14.jpg)
14
With Mini Partitions • Flow exit regions become much smaller• Increased convection near exit regions
Figure 2.12: Cross-Sections of Heat Sink/PCH Temperature With PartitionsBinh Tran
![Page 15: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/15.jpg)
Vapor Chamber• Heat Spreader• Increase conduction in heat sink base
15Patil, UTA 2015Figure 2.13: Vapor Chamber Icepak ModelBinh Tran
![Page 16: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/16.jpg)
1616
Figure 2.14: Heat Sink/ PCH assembly with standard base
Figure 2.15: Heat Sink / PCH assembly with vapor chamber base 16
![Page 17: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/17.jpg)
Outline• Introduction• Testing & Simulation
•Results• Conclusion
17Ryan Hart
![Page 18: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/18.jpg)
18
Simulation Results vs. Experiment Results
• Mean PCH Temperature (100% CPU Utilization)• Simulation: 61.86 ± 1.47• Experimental : 61.83
• Worst case % Error: 2.4%
Idle
40%60%
80%100%
MEM
+ CPU
50
52
54
56
58
60
62
64
66
68
70
55.0
4
60.1
3 61.8
7
62.0
1
61.8
3 64.0
5PCH
CPU Utilization %
Mea
n PC
H T
empe
ratu
re (°
C)
Figure 3.1: Extruded Fin Experimental results for different power utilizationsRyan Hart
![Page 19: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/19.jpg)
Baseline Test Results
19
• Cross-Cut fin lowest temperature for base heat sinks
• Extruded fin, elliptical, and circular pins have roughly same range of temperature
Figure 3.2: Maximum PCH Temperature for Heat Sinks without Modifications
Ryan Hart
![Page 20: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/20.jpg)
Mini Partition Test Results
20
• Lowers cross-cut fin, elliptical and square pin temperatures• High reduction in square pin
PCH temperature• Negligible or
detrimental effect on hexagonal and circular pin fins• Possible interference with
flow mixing
Figure 3.3: Maximum PCH Temperature for Heat Sinks Mini PartitionsRyan Hart
![Page 21: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/21.jpg)
Vapor Chamber Test Results
21
• Lower PCH temperatures on all designs• Heat spreading increases
potential convection• Higher temperature
drop in cross-cut, extruded fin and circular pin heat sinks
• greater effect for denser heat sinks
Figure 3.4: Maximum PCH Temperature for Heat Sinks with Vapor Chamber basesRyan Hart
![Page 22: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/22.jpg)
Partitions + Vapor Chamber
22Figure 3.5: Maximum PCH Temperature for Heat
Sinks with both Mini Partitions and Vapor ChambersRyan Hart
![Page 23: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/23.jpg)
Outline• Introduction• Testing & Simulation• Results
•Conclusion
23Damone Norwood
![Page 24: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/24.jpg)
Final Design
24Damone Norwood
• Cross-Cut Fin• Thermal Improvement• No Modification- 2°C
• 2.9% Temp. decrease• VC + Mini Partition - 4.3°C
• 6.2% Temp. decrease
Figure 3.6: Final Heat sink Design
![Page 25: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/25.jpg)
Summary • Modeled server in Icepak• Implemented non-conformal meshing• Experimental Testing to validate CFD model within 5% error• Developed final design & server improvements• PCH temperature reduction of 6%
25Damone Norwood
![Page 26: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/26.jpg)
Discussion
26
Questions?
![Page 27: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/27.jpg)
Works Cited
27
[9] Patil, Dhanraj Arun. “CFD Modeling and Parametric Study of Vapor Chambers as Heat Spreaders for High-Power Electronic Devices” Master’s Dissertation, Department of Mechanical Engineering, University of Texas at Arlington, Arlington, TX, 2015
![Page 28: Senior Design Final Presentation (Fin)](https://reader038.vdocuments.net/reader038/viewer/2022110219/586fa4181a28abcc238b77f5/html5/thumbnails/28.jpg)
Further Work• Additional Physical Model Testing• Recirculating Flow • Ducting and Vapor Chamber
• Further Design Considerations
• Quantify power savings from cooling• Both (internal fan and coolant)
26Damone NorwoodFigure 3.3: Winterfell 2OU Hybrid Cooling
Server Rack