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Heatsink Design A practical Approach

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Title: Heatsink Design A practical Approach


1
Heatsink Design A practical Approach
  • Sridevi Iyengar
  • Global Application Engineer
  • Sapa Profiles

2
Agenda
  • Introduction
  • Heat sinks and Heat Transfer mechanisms
  • Why use a heatsink
  • Some facts you (N)ever wanted to know about
    heatsink
  • Thermal Interface materials
  • Liquid coolers
  • Friction Stir Welding

3
About Me Sridevi ( Sri )
  • Joined Sapa in 2010
  • Have 10 years of experience in electronics
    cooling and thermal design. Worked mostly at
    telecom/networking companies or consulted for
    projects in these areas.
  • Thermal Analysis, thermal testing some of my
    key strengths, area of expertise
  • Icepak, Flotherm, and currently Flow Simulation
    are the tools I have used extensively for thermal
    simulations
  • Education
  • B.S Chemical Engineering NITK Suratkal (
    Karnataka Regional Engg College)
  • M.S - Computational fluid Dynamics University
    of California San diego
  • Passionate about South Indian Classical Music. I
    learn, teach and perform regularly

4
What is a heatsink
  • Heatsinks are devices that enhance heat
    dissipation from a component to a cooler ambient
    usually air, but sometimes to other fluids as
    well.
  • The primary purpose of a heatsink is to maintain
    the temperature of the device being cooled within
    acceptable limits as specified by the component
    manufacturer.
  • Keeping the component temperature under the
    specified limits ensures proper operation of the
    device, and improves reliability and life of
    component.

5
Factors to be considered while designing heatsinks
  • Power that needs to be dissipated
  • Maximum allowable component temperature
  • Available space/volume for heatsink
  • Power density
  • Air Flow parameters
  • Pressure Drop
  • Bypass effects
  • Manufacturability
  • Costs

6
Heat sinks for air cooling
Aluminium alloys are the dominating materials
for air-cooled heat sinks
7
Thermal conductivity of Al-alloys
Copper (pure) 395 W/mK
8
Principles of heat transfer
  • Heat transfer is the science which seeks to
    predict the energy transfer which may take place
    between material bodies as a result of
    temperature difference
  • The three modes
  • Conduction Energy transfer within solids
  • Convection Transfer from a surface to a moving
    fluid
  • Radiation transfer by electromagnetic radiation

9
Convection Cooling
  • Convection cooling achieved by two ways
  • Forced Convection
  • Air is forced over the components with a fan or
    blower
  • The velocity of air depends on the fan and the
    local conditions
  • Natural Convection or free
  • The buoyancy effect forces hot air to flow to the
    top and cold air to come to the bottom.
  • Typical velocity 0.2 m/sec

10
Conduction
11
Convection
12
Radiation
13
Technical terms
  • Q Total power that is dissipated by the device
    (s) being cooled (W)
  • Tj Junction temperature of the device
  • Tc Case temperature of the device
  • Ts Heatsink temperature - Maximum
    temperature of the heatsink at a
    location closest to the device
  • Ta Ambient temperature

14
The basic equation
  • The governing equation which correlates the total
    power, temperature difference and the thermal
    resistance can be expressed as

The thermal resistance is analogous to the
electrical resistance used in Ohms law.
15
Thermal Resistance

Rj-c is the Junction to case thermal resistance.
Usually a parameter that is published by the
component manufacturer
Rc-s is the thermal resistance across the
thermal interface material between the heatsink
and the component.
Rs-a is the thermal resistance of the heatsink.
Junction to Ambient is the sum of the resistances
16
Heatsink Selection
Tj, Rjc and Q will be provided by the component
manufacturer. Rcs Thermal resistance of the
interface material Ta Ambient temperature
Ta and Rcs are parameters that we can control to
a certain extent Rsa is the number that will help
us identify a heatsink that will meet our
criteria.
17
Heatsink Design parameters
  • A heatsink can be optimised for performance by
    varying the different dimensions shown.
  • Of course, the optimised design should consider
    manufacturability.

18
Air-cooled heat sinks forced convection - fan
curve
Fan law
Air flow ? n (rpm) Pressure drop ? n2 Noise ? n3
19
Fin efficiencyApparent cooling area vs.
effective cooling area
q hA (Ths-Tair)
20
Bypass Effects in Forced Convection
When there is a significant gap between the
heatsink and the top surface of the enclosure air
will bypass the heatsink. This reduces the
performance of the heatsink. Bypass effect is
more pronounced in heatsinks with closely packed
fins.
HHeatsink Fin
HHeatsink Base
Here the air is forced to go through the heatsink
and in this case the performance of the heatsink
is optimised.
21
Conical fins vs. rectangular fins
Conical fins seems have some advantages when only
heat flow is considered
Die casting always need a relief angle !
22
Air flow in a conical channel
When both air flow and heat flow are considered,
rectangular fins are better
23
Cooling at Altitude
24
Heat sink orientationnatural convection
  • The buoyancy effects of air forces hot air to
    move up and cold air to come down.
  • Orient the heatsink keeping in mind the direction
    of gravity
  • Fin thickness and fin pitch are important factors
    to consider while optimising the heatsink.

gravity
25
Comments on heat sinks used for natural convection
  • Optimise the fin spacing according to temperature
    and height.
  • Proper orientation of the heatsink with respect
    to gravity is important.
  • Radiation heat transfer must be considered.
  • Proper surface treatment is often needed as this
    increases the emissivity.

26
Heatsink OrientationForced convection
  • Fluid is forced to flow over the surface by
    external help (Fan)
  • Orient the heatsink in the direction of the
    Airflow.
  • Sometimes when the flow is erratic, can use pin
    fin heatsinks.
  • In general, extruded plane fin heatsinks work
    better and have lesser pressure drop across the
    Heatsink.

27
Comments on Heatsinks used for forced convection
  • Design must take the fan curve (and by-pass flow)
    into account when appropriate.
  • Check the fin efficiency when the fin is fairly
    tall.
  • Avoid using conical fins.
  • Optimise the base thickness, fin thickness and
    fin spacing based on the expected air velocity
    through the channels.
  • Always remember that when you have more than one
    heatsink in the system, the airflow to the
    downstream heatsink will be affected by the
    upstream heatsinks and components.

28
Conduction, contact surface
Actual contact area lt 2 of apparent contact
area
  • Perfect contact can never be ensured between
    the heatsink and the package.
  • This could lead to potential problems since
    trapped air acts as an insulator.
  • The performance of the heatsink can be much
    lower than estimated leading to high component
    temperatures.
  • To combat this problem, it is necessary to use
    a thermal interface material.

29
Thermal interface materials Different types
  • Double sided PSA
  • Pressure sensitive adhesive is used to adhere the
    heatsink to the heat source
  • Easy to assemble with protective liner tabs
  • The component package type will determine the
    kind of tape to use acrylic based or silicone
    based
  • The thermal conductivity of these tapes are
    moderate and depends on their thermal performance
    depends on the contact area that can be achieved
    between the bonding surfaces
  • Typically 0.005 -0.10 thick
  • Not recommended when the heatsink fins are
    oriented vertically i.e along the direction of
    gravity
  • Single sided PSA
  • Provides adhesion only to the heatsink.
  • Mechanical fastening of the heatsink to the
    component is needed.
  • Typically 0.05 0.01 thick

30
Thermal interface materials Different types
  • Phase Change Material
  • Available as peel and stick pads at room
    temperature
  • When heated the material reflows to fill all the
    interface voids
  • Very good performance high thermal conductivity
  • Conforms to minimize thermal path thickness
  • Mechanical fastening of heatsink is required
  • Could be messy during re-work
  • Gap Filler
  • Soft, thermally conductive silicone elastomers.
    Used in places where a large and variant gap
    exists between the components and heatsink
  • Typically used in places where a common heatsink
    is used for multiple components
  • Mechanical fastening of heatsink required
  • 0.5mm 5 mm thickness

31
Thermal interface materials Different types
  • Epoxy
  • Room temperature vulcanizing materials which
    function both as thermal pathway and mechanical
    attachment
  • Not favored by assemblers due to the possible
    prep work and inability to rework
  • Grease
  • Excellent thermal conductivity and void filling
    capability
  • Mechanical attachment of heatsink to component
    required
  • Can be messy and not favored by assemblers
  • Can be as thin as 0.01

32
What Next
  • At some point one reaches the limit of Air
    cooling.
  • You may enhance the performance of the heatsinks
    with different techniques like, serrated fins,
    bonded fins, Skived fins.
  • Heatpipe heatsinks, Vapor chamber and Liquid
    cooled heatsinks are the next generation of
    thermal management products when Air cooled
    heatsinks just will not do the job for you.

33
Heat pipe
Heat pipe
Vapour flow
wick
Condense returning (by capillary)
Heat in
Heat out
34
Heat pipes
35
What is liquid cooling?
  • Conventional definition in automotive analogy
  • Circulating fluid driven by pump
  • Heat absorbed at source by cold plate! Or water
    block
  • Heat rejected to ambient by heat exchanger or
    radiator
  • Multiple heat sources possible in series or
    parallel
  • May also include two phase flow, evaporating at
    heat source, e.g.
  • Heat pipe
  • Thermsyphon

36
Liquid cooling Channel design is important.
30
199
37
Liquid cooling temperature flow
Sapas channel
Star channel
38
Disadvantages of liquid coolingSystem becomes
more complex
  • Add significant complexity more parts and more
    units being involved
  • Pump reliability
  • Low heat flux parts still need cooling with
    heatsinks/Fans
  • Investment required for testing and verifying
    system performance
  • Still need to remove heat from liquid system to
    ambient air (or other liquid)
  • In general, liquid cooling units will require
    more real estate.

39
Some comments on liquid cooling
  • Channel design is important.
  • Contact thermal resistance between component and
    heat sink may becomes significant.
  • The choices of liquid (coolant) depends on single
    phase or two phase.

40
Friction stir welding
  • A rotating tool is plunged into the joint line
    and moved along the joint. Neither flux nor
    filler material are used.
  • Friction Stir welding method of joining is based
    on the fact that the metal is subjected to heavy
    plastic deformation at high temperatures, but
    lower than the melting point.
  • When the rotating tool is plunged into the metal,
    friction heat is generated. The tool produces
    severe plastic deformation under high pressure,
    during which the weld interfaces are stirred
    together and a homogenous structure is formed.
  • Process results in completely pore-free,tight
    joints with a high strength
  • Minimum heat influence on the material
  • Good mechanical properties

41
Friction Stir Welding
42
Final Thoughts
  • Global market for Electronic Thermal management
    is forecasted to reach 8.6 billion by 2015.
  • Miniaturization of products along with increase
    in features is leading to higher power
    dissipations and more importantly power density
  • Upfront, well thought out thermal design will
    eliminate thermal related problems at later
    stages. At this time there might be no recourse
    or if there is one, it might be an expensive one.
  • Working closely with your thermal solutions
    provider will ensure you have a solid thermal
    solution for your electronic product.

43
Sapas offer to you...
44
Thank You
  • Feel free to contact me if you think I can be of
    any help.
  • Sridevi.iyengar_at_sapagroup.com
  • 91 99000 45726
  • Some websites that I visit for information on
    thermal design
  • www.coolingzone.com
  • www.electronics-cooling.com
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