kasra nakhaee
TRANSCRIPT
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Contents
• Introduction………………………………………………………………………………. 3
• Principle of Heat Pipe operation………………………………………………… 4
• Heat Pipe Types…………………………………………………………………………. 10
• HPHXs & Applications………………………………………………………………… 28
• HPHX Types……………………………………………………………………………..... 31
• References…………………………………………………………………………………. 40
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Introduction
• Heat pipe concept described in 1942
• ‘Heat Pipe’ term was used in 1963
• High heat transport characteristics due to Use of Latent Heat
• No Energy Required for its Operation
• It was developed originally for the gravity-free environment
• Increasing usage in many industrial applications
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• HP consists:
• Closed container
• Working fluid
• Porous capillary wick
• One end functions as evaporator
• The other end functions as condenser
• P = Psat at its operating temperature
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Principle of Heat Pipe operation
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Principle of Heat Pipe operation
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• Thermodynamic cycle:
• 1-2 Heat applied to evaporator through external sources vaporizes working
fluid to a saturated(2’) or superheated (2) vapor.
• 2-3 Vapor pressure drives vapor through adiabatic section to condenser.
• 3-4 Vapor condenses, releasing heat to a heat sink.
• 4-1 Capillary pressure created by menisci in wick pumps condensed fluid into
evaporator section.
• Process starts over.
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Principle of Heat Pipe operation
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• Thermodynamic cycle:
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Principle of Heat Pipe operation
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• Limits:
• Wicking
• Entrainment
• Sonic
• Boiling
• Flooding
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Principle of Heat Pipe operation
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Principle of Heat Pipe operation
MEDIUMMELTING PT. (° C )
BOILING PT. AT ATM. PRESSURE
(° C)
USEFUL RANGE
(° C)
Helium
Ammonia
Water
Silver
- 271
- 78
0
960
- 261
- 33
100
2212
-271 to -269
-60 to 100
30 to 200
1800 to 2300
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a) Tow-Phase Closed Thermosyphon
b) Capillary-Driven Heat Pipe
c) Annular Heat Pipe
d) Vapor Chamber
e) Rotating Heat Pipe
f) Gas-Loaded Heat Pipe
Heat Pipe Types
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g) Loop heat pipes (LHP)
h) Capillary Pumped Loop Heat Pipe
i) Pulsating heat pipes (PHP)
j) Micro and Miniature Heat Pipe
k) Inverted Meniscus Heat Pipe
l) Nonconventional Heat Pipe
Heat Pipe Types
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Heat Pipe Types
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a) Two-Phase closed Thermosyphon:
• Gravity-assisted wickless
• Sonic and vapor pressure limit
• Flooding limit and boiling limit
• Thermosyphons are often several meters long
• prevent permafrost melting along pipelines, roads and train-rails
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Heat Pipe Types
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• About 120,000 heat pipes were installed along the Trans Alaska Pipeline
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Heat Pipe Types
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b) Capillary-Driven Heat Pipe:
• Wick provide capillary-driven pumping
• Capillary limit
• Using in almost all laptop computers
• Various commercial and aerospace applications
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Heat Pipe Types
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c) Annular Heat Pipe:
• Similar to capillary-driven heat pipe
• Main difference in cross section of vapor space
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Heat Pipe Types
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d) Vapor Chamber
• Capillary-driven planar
• Additional wick blocks
• Can be placed in direct contact with CPU
• Excellent candidate for electronic cooling applications
• Electronic cooling with heat fluxes higher than 50 𝑊 𝑐𝑚2
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Heat Pipe Types
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e) Rotating Heat Pipe
• designed to cool machinery by removing heat through a rotating shaft
• rotating heat pipe uses centrifugal forces
• design in tow configuration: a) circular cylinder b) disk type
• a)Cooling rotating parts of electric motors and metal-cutting tools
• b)Cooling turbine components and automobile brakes
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Heat Pipe Types
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e) Rotating Heat Pipe
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Heat Pipe Types
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e) Rotating Heat Pipe
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Heat Pipe Types
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f) Gas-Loaded Heat Pipe
• Same as capillary-driven heat pipe
• Difference : a noncondensing gas introduced into the vapor space
• Result: nearly constant evaporator temperature regardless of the heat input
• Using for an isothermal furnace and for electronic cooling
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Heat Pipe Types
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f) Gas-Loaded Heat Pipe
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Heat Pipe Types
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g) Loop Heat Pipe
• Compensation chamber
• 2 wick structure in evaporator
• Long thermal transport distance
• Attractive for spacecraft cooling
• Alternative for Thermal control device in scientific heat regulation
• and telecommunication satellites
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Heat Pipe Types
g) Loop Heat Pipe
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Heat Pipe Types
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i) Pulsating Heat Pipe
• Two type: a)looped, b)unlooped
• Self-excited oscillatory motion
• No wick structure
• Weighs less than conventional heat pipe
• Surface tension has a great role in the dynamics of PHP
• Space applications, thermal control of electrical devices
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Heat Pipe Types
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k) Micro & Miniature Heat Pipes
• 10 μ < Dh <500 μ (micro) , 0.5 mm < Dh < 5 mm (miniature)
• Container from silicon
• Polygonal cross section
• Power Electronics, Electric Train, Air Conditioning(Rood Heating), Aerospace
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Heat Pipe Types
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k) Micro & Miniature Heat Pipes
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Heat Pipe Types
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l) Nonconventional Heat Pipes
• Different geometries
• Examples:
• Polygonal: micro Heat Pipe
• Leading edge: future hypersonic aircraft
• Cover the leading edge of the wings and engine nacelles
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HPHXs Applications
a) HVAC
b) Waste heat recovery from combustion gases
c) Data center cooling
d) Power plant dry cooling towers
e) Steam condensers
f) Latent thermal energy storage solar power generation
g) CPU cooling in laptop computers
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HPHXs Applications
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HPHXs Applications
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HPHX Types
1. Conventional HPHX
2. PCM-HPHXs
3. Conventional HPHSs
4. PCM-HPHSs
5. Reflux heat exchanger (RHXs)
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1. Conventional HPHXs and Applications
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1.1. HVAC systems
1.2. Bakery
1.3. Metal forging
1.4. Automotive
1.5. Data center cooling
1.6. Power plant cooling tower
1.7. Nuclear spent fuel cooling
1.8. Solar water heating
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1. Conventional HPHXs and Applications
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1. Conventional HPHXs and Applications
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1. Conventional HPHXs and Applications
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• 2.1. General thermal energy storage
• 2.2. Solar thermal power generation
• 2.3. Data center cooling
• 2.4. Automotive
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2. PCM-HPHXs and Applications
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• 3.1. Electronics/CPU cooling using HPHSs
• 3.2. Permafrost stabilization
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3. HPHSs and Applications
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• 4.1. Electronics/CPU cooling using HPHSs
• 4.2. Spacecraft thermal management
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4. PCM-HPHSs and Applications
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• 5.1. Solar water heating
• 5.2. Nuclear rector cooling
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5. Reflux Heat Exchangers and Applications
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References
• Hamidreza Shabgard, Michael J. Allen, Nourouddin Sharifi, Steven P. Benn , Amir Faghri ,Theodore L. Bergman,
2015. Heat pipe heat exchangers and heat sinks: Opportunities, challenges, applications, analysis, and state of
the art. International Journal of Heat and Mass Transfer
• Leonard L. Vasiliev, 2005. Review Heat pipes in modern heat exchangers. Applied Thermal Engineering
• Faghri, Amir, 2012. Review and Advances in Heat Pipe Science and Technology. Journal of Heat Transfer
• Greg F. Naterer, 2008. Heat Exchangers and Heat Pipes. US: Taylor &Francis
• Faghri, Amir, 1995. Heat Pipe Science and Technology. US: Taylor &Francis
• Saunders, E. A. D, 1988. Heat exchangers : selection, design & construction. UK: Longman Scientific & Technical, Wiley
• http://www.1-act.com/rotating-heat-pipes/
• http://www.hexag.org/news/32/sterling.pdf
• http://dtic.mil/dtic/tr/fulltext/u2/a073597.pdf
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