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Title: Vapor Compression Cooling VCC in Electronics


1
Vapor Compression Cooling (VCC) in Electronics
2
Outline
  • Benefits
  • Disadvantages
  • History
  • Basic operation
  • Engineering Design
  • Cold plate
  • Refrigerants
  • Capillary tube
  • Condensation
  • Product Reliability
  • Current applications
  • Supercomputer and Mainframe Cooling
  • Current research
  • Microscale VCRS

3
Benefits
  • Allows cooling to below ambient temperatures,
    increasing performance, reliability, and allowing
    operation in higher temperatures.
  • High COP (around 2 to 3).
  • Ability to remove very large heat loads.
  • Widely available compressor and fan only moving
    parts, stable, and reliable. (moran, 2001).
  • Low mass flow rate of refrigerant needed.
  • Ability to transport heat away from its source.
  • COP up to 3 times greater than thermoelectric
    coolers or more.
  • (peeples, 2001)

4
Benefits
  • Sub ambient temperature operation allows CMOS
    (complementary-symmetry/metal-oxide
    semiconductor) transistors to switch on and off
    faster (peeples, 2001).
  • CMOS circuits are a major class of integrated
    circuit and include microprocessors,
    microcontrollers, and other digital logic
    circuits (Wikipedia, http//en.wikipedia.org/wiki/
    CMOS) .

5
Benefits
  • The following physical parameters favor low
    temperature operation carrier mobility, and
    junction leakage.
  • Although at low temperatures there is an increase
    in the failure rates due to hot carriers, overall
    failure rates decrease at lower temps due to the
    overall increased characteristics mentioned
    previously (Moran,2001).
  • Definitions
  • Carrier mobility- velocity of charge carriers in
    a solid material with an electric field applied
    to it (Wikipedia, http//en.wikipedia.org/wiki/Ele
    ctron_mobility).
  • Hot carriers- high energy carriers (Moran,2001).
  • Junction leakage-undesirable conductive paths in
    certain components, for instance, in capacitors.
    Also, a pathway through which electric discharge
    may slowly take place (IEEE Standard Dictionary
    of Electrical and Electronics Terms).

6
Benefits
  • Much like heat pipes, vapor compression coolers
    use the high heat of vaporizations of the working
    liquid to remove large amounts of heat.
  • Therefore, low mass flow rates required.
  • Advantage over a chilled liquid loop that
    requires a much higher mass flow rate.
  • Much like heat pipes, VCCs use the high heat of
    vaporization of liquids to transport large
    amounts of heat, thus low amounts of liquid are
    required. However, in chilled liquid loop
    coolers, the liquid is heated but not necessarily
    evaporated.

(Cengel and Boles, 2002)
7
Disadvantages
  • The cost of employing the cooling system may be
    10-20 of the cost of the entire system.
  • Large space and input power.
  • The disadvantages of the cooling system has to be
    weighed with the large advantages. A lot of
    times, traditional methods of cooling like air
    cooling is not feasible so a VCC is required.
  • However, if the cooling requirements can be
    satisfied with traditional techniques, the
    traditional technique are the preferred cooling
    method (Moran, 2001).

8
History
  • The vapor compression refrigerator was first
    proposed in 1805 and a model was constructed in
    1834.
  • Vapor compression technology is well established
    but only recently used in electronics cooling.
  • Kryotech was one of the first companies to employ
    the technology.
  • By the late 90s companies like AMD, Sun
    Microsystems, IBM, and SYS Technologies had all
    used Vapor Compression cooling.

(Schmidt et al., 2002)
9
Basic Operation
(Peeples,2001)
10
Basic Operation
  • Ideal cycle
  • 1-2 The working refrigerant, a saturated vapor,
    is carried through the suction tube to the
    compressor. The compressor compresses the
    saturated vapor into a superheated vapor which is
    then passed to the condenser.
  • 2-3 The heat of the hot and high pressure vapor
    is released into the environment from the
    condenser. The working gas is transformed into a
    saturated liquid.
  • 3-4 The liquid is pumped through a capillary tube
    or a thermal expansion valve into the evaporator,
    dropping significantly in temperature. The
    working fluid is a saturated mixture.
  • 4-1 Heat flows into the evaporator from the heat
    source. The heat vaporizes all the working liquid
    (refrigerant), at the end of this stage the vapor
    is saturated, and the process repeats.

(Peeples,2001)
11
Basic Operation
  • Qout, QH denotes the heat released to the
    environment.
  • Qin, QL denote heat absorbed from the
    refrigerated space.
  • 2 represents the actual position of the state. 2s
    represents the position of the state if it were
    irreversible.
  • In the ideal case
  • 1?2 isentropic (sconst)
  • 2?3 isobaric (Pconst)
  • 3?4 isenthalpic (hconst)
  • 4?1 isobaric ( Pconst)

(Peeples,2001)
12
Basic Operation
  • The heat absorbed by the evaporator (Qin)
    released from the condenser (Qout), and actual
    and isentropic work input by the compressor can
    be determined from the equations
  • The efficiency of the compressor is given by
  • Where h is the enthalpy at various states, the
    subscripts s and a refer to isentropic and
    actual, and w refers to work.

(Cengel and Boles, 2002)
13
Basic Operation
  • Actual cycle
  • The deviation of the ideal cycle to the actual
    cylce is due to irreversibilities mainly due to
    fluid friction-causing pressure drops and heat
    transfer to the system or the environment.
  • In the ideal cycle the state of the refrigerant
    is precisely know, for example, at stage 1 the
    refrigerant is a saturated vapor. However, in
    actuality the state of the refrigerant may not be
    precisely known and is usually a superheated
    vapor.

(Cengel and Boles, 2002)
14
Basic Operation
  • Note that the pressure drops between stages 8-1,
    2-3,4-5 etc. cause alterations
  • to the TS diagram. The process 1-2 represents a
    compression path that may
  • be more desirable than the 1- 2 pathway because
    the specific volume
  • of the refrigerant is lower and thus the work
    input is lower.

(Cengel and Boles, 2002)
15
Basic Operation
(Cengel and Boles, 2002)
16
Basic Operation
  • The Coefficient of performance of the VCR is the
    ratio of heat into the evaporator to work put
    into the compressor. Generally, the COP is around
    2 to 3.
  • The COP can be determined by finding the ratio of
    the enthalpies between the throttling valve and
    evaporator and between the evaporator and the
    compressor.

(Cengel and Boles, 2002)
17
Basic Operation
  • The most efficient refrigeration cycle is that of
    a Carnot refrigerator.
  • The coefficient of performance of the Carnot
    refrigerator gives the maximum performance
    between two hot and and cold temperatures.
  • This value can be compared to the actual COP to
    determine how close to ideal the refrigerator is
    operating.
  • Note that the Carnot cycle is a reversible cycle.
    Reversible cycles are cycles that do not generate
    any entropy due to friction, heat transfer, etc.
    For a reversible cycle

(Cengel and Boles, 2002)
18
Basic Operation
  • The coefficient of performance for a Carnot cycle
    is
  • Note the COP increases as the ratio of TH/TL
    decreases. Therefore, we want TH and TL to be as
    close as possible. Usually, TL is specified and
    TH can be altered. The reason for TH/ TL
    affecting COP is that for a given TL the greater
    the TH the greater the amount of work input,
    decreasing COP.

(Cengel and Boles, 2002)
19
Basic Operation
  • The area enclosed in the TS diagram generally
    describes the net heat transfer and the work of
    the system. For refrigeration, work input lowers
    the COP for a given heat rejection therefore,
    altering the states of the cycle to get a smaller
    enclosed area will increase performance.

(Cengel and Boles, 2002)
20
Engineering Goals
  • The design of a cost-effective and efficient VCC
    involves the following considerations
  • Cold surfaces can not be allowed to collect
    condensate from the air.
  • The most suitable refrigerant for the given
    application, as well as the tubing to supply and
    remove the refrigerant, must be chosen.
  • Compressor and condenser design.
  • The cold plate must efficiently lift heat from
    the device to be cooled.

(Peeples,2001)
21
Cold Plate/Evaporator
  • The cold plate (evaporator) is a heat exchange
    device which transfers heat from the heat source
    to the working fluid.
  • Cold plate design must assure efficient heat
    transfer from the device being cooled to the
    refrigerant inside the cold plate.
  • The cold plate must be fabricated from thin and
    thermally conductive material to minimize thermal
    resistance while maintaining structural
    stability.
  • The mating surface between the cold plate and the
    heated body must be flat and smooth to minimize
    contact resistance.

(Peeples,2001)
22
Refrigerant Fluids
  • The refrigerants physical properties determine
    its evaporating temperature at a specified
    operating temperature, as well as, its capacity
    to transport heat.
  • The well known refrigerants R-134a and R-404a
    (and others) perform well for cooling high power
    electronics due to their high heat transport
    characteristics, low possibility of environmental
    harm, corrosion, and risk of explosion.

(Peeples,2001)
23
Refrigerant Fluids
  • When making a decision as to which refrigerant to
    use and under what pressures to operate the VCR,
    consideration of the refrigerants temperature of
    vaporization and condensation should be
    considered. If the temperature of the refrigerant
    doesnt reach the vaporization point (at the
    operating pressure) the VCR will not work
    properly. To ensure a proper heat transfer rate a
    5 to 10 degree Celsius temperature difference
    should be maintained between the evaporator and
    the condenser with the refrigerant.
  • The next slide shows the P-T curves of R-404a and
    R-134a describing the refrigerants lowest
    practical operating limit.

(Peeples,2001)
24
Refrigerant Fluid Saturation Pressure and
Temperature
(Peeples,2001)
25
Capillary Tube
  • The capillary tube has the function of
    transporting the working liquid from the
    condenser to the evaporator.
  • The small diameter and long length of the tube
    produces a large pressure drop.
  • Refrigerants chosen have a large Joule-Thomson
    coefficient, which tells us how much the
    temperature drops as the pressure drops at
    constant enthalpy.
  • Since pressure drops create performance losses
    careful design must be taken so that the tube
    lengths and diameters are minimal.
  • (Heydari, 2002)

26
Condensation
  • Condensation, much like in TEC, is a problem
    because the surfaces of the VCR may be lower than
    the dew point.
  • Since water is hazardous to electronic
    assemblies, condensation must be minimized by
    insulating surfaces from air in spot-cooling
    applications. (Peeples,2001)
  • More on sealants later on in the slides.

27
Product Reliability
  • Electro-mechanical systems generally have product
    life cycles called bathtub curves.
  • The curve has three distinct regions
  • Infant mortality- rate of failure decreases with
    time
  • Normal use-rate of failure relatively constant
  • Wear out- rate of failure increases with time.

(Peeples,2001)
28
Improving Performance
  • In some applications the heat rejection demands
    (efficiency or amount) are higher than what can
    be handled by a vapor compression cycle running
    on a regular cycle. In these cases, modifications
    of the cycle must occur.
  • Like previously mentioned, modifying the TH/TL to
    get them as as low as possible will increase
    performance but larger modifications may need to
    be made.

(Cengel and Boles, 2002)
29
Improving Performance
  • An example is a cascade cycle, which performs the
    refrigeration process in two cycles that are in
    series. This is useful in situations
    (industrial), where there is a large temperature
    difference between the hot and cold side for one
    cycle to be practical.
  • If the fluid used in the cascade system is the
    same, the heat exchanger can be replaced by a
    mixing chamber, known as a flash chamber which
    has better heat transfer characteristics.

(Cengel and Boles, 2002)
30
Cascade Refrigeration
(Cengel and Boles, 2002)
31
Refrigeration System w/ Flash Chamber
(Cengel and Boles, 2002)
32
Supercomputer and Mainframe Cooling
  • The extremely high cooling demands of mainframes
    and supercomputers are ideal applications for
    VCRs because other cooling systems can not
    provide the necessary cooling capacity. An
    example of is IBMs G4 mainframe (shown on the
    next slide)

(Schmidt et al.,2002)
33
Supercomputer and Mainframe Cooling

(Schmidt et al.,2002)
34
Supercomputer and Mainframe Cooling
  • The bulk power assembly at the top provides 250
    volts dc to the mainframe.
  • Below the bulk power is the central electronic
    complex where the MCM (multichip module) is
    located. The MCM housing the 12 processors.

35
Supercomputer and Mainframe Cooling
  • Below the MCM are blowers that provide air
    cooling for all of the components in the
    processors except for the processor module, which
    is cooled by refrigeration.
  • Below the blowers are two modular refrigeration
    units (MRUs-the VCR) which provide cooling via
    the evaporator mounted on the processor module.
  • In the bottom of the mainframe are the input/
    output (I/O)connections and two blowers. The
    blowers cool the I/O connections, as well as,
    provide the cooling for the condenser of the
    MRUs.

(Schmidt et al.,2002)
36
Multichip Module (MCM)
  • The mainframes processing unit, MCM, is
    constructed as follows.
  • Note the evaporator above the chips.

(Schmidt et al.,2002)
37
Modular Refrigeration Unit (MRU)
  • The MRU (VCR) houses all the refrigeration
    components except the evaporator. The MRU
    contains the
  • Condenser
  • Thermostatic expansion valve
  • DC rotary compressor

(Schmidt et al.,2002)
38
Condensation Protection
  • To avoid moisture condensation on the MCM
    hardware, all the cooling hardware including the
    evaporator copper cold plate is contained in an
    airtight metal enclosure with one open face.
  • 260 grams of silica gel desiccant is kept there
    to absorb any moisture leaking into the enclosure.

(Schmidt et al.,2002)
39
Condensation Protection
  • The figure on the previous slide also shows a
    flat board that replaced the planar board in
    order to test the effectiveness of various
    sealants in keeping moisture out of the
    evaporator cavity.
  • The results show that the
  • Butyl 1 rubber sealant
  • displayed the best
  • sealant characteristics,
  • allowing the least amount
  • of humidity to enter.

(Schmidt et al.,2002)
40
Microscale VCRs
  • To utilize VCRs in laptops, personal computers,
    or other cooling applications of small size, the
    VCR size must be reduced to fit within a small
    enclosure. The next section discusses progression
    in this area.
  • Since miniature VCRs have high heat loads to
    transfer away, the condenser and evaporator must
    be designed such that they transfer enough heat
    to satisfy the heat removal demands.
  • The most difficult part in designing a miniature
    VCR is the compressor.

41
Microscale Evaporators
  • Chirac et al. (2005) suggest using an evaporator
    with microchannels through the center as an
    option to miniaturize the evaporator. The
    microchannels transfer large amounts of heat
    reducing the evaporator size needed to transfer
    the heat load from the heat source.

42
Microscale Condenser
  • Chiriac et al. also describe a condenser with
    microchannels through the center. A heat sink
    surrounds the outside of the condenser while a
    fan blows air over the heat sink.

43
Refrigerant Fluids
  • Heydari (2002) performed a simulation with a
    miniature VCR which included a miniature
    compressor to cool a computer system.
  • The figure shows ammonia has the highest COP
    relative to the other refrigerants. However, when
    the refrigerants cost, environmental impact
    (ozone depletion and global warming potential),
    and safety issues were considered, Heydari
    concluded the optimal refrigerant to use is R134a.

44
Condenser Temperature and Performance
  • Heydari found that with the computer chip
    junction temperature and heat absorbed by the
    evaporator fixed, decreasing the condenser
    temperature decreases the COP.

45
Evaporator Temperature and Performance
  • Lastly, Heydari found that for a fixed junction
    temperature and the amount of heat absorbed by
    the evaporator fixed, increasing the evaporator
    temperature increases the COP but the amount of
    heat condensed decreases.

46
Refrigerant Fluids
  • When it comes to the performance of refrigerants
    in miniature VCRs, Phelan et. Al. (2004)
    performed experimental analysis comparing three
    refrigerants ammonia, R-134a, and R-22 to
    determine which of the three produce the highest
    COP for a miniature VCR under various conditions.
  • The factors tested were the evaporator and
    condenser temperatures, as well as, the
    efficiency of the compressor which was predicted
    to decrease as the size of the compressor
    decreased. The results are shown on the next
    slide.

47
Refrigerant Fluids
Phelan et. Al. (2004)
48
Refrigerant Fluids
  • For each condition, ammonia has the highest COP.
  • The higher COP values are due to ammonias
    greater latent heat of vaporization.
  • However, due to ammonias greater adverse
    environmental and physiological effects, R-134a
    is more predominantly used.
  • Ammonia is typically used only with a secondary
    loop due to its toxicity.

(Phelan et. al 2004)
49
Microscale VCRs
  • Utilizing VCRs for electronics cooling
    applications has been limited by their large size
    due to the use of traditional components like
    pistons, linkages and pressure vessels.
  • University of Illinois has a DARPA grant to
    develop miniature VCRs for use with cooled
    military uniforms for use in desert warfare. This
    Technology could also be used for electronics
    applications. However, the miniature compressor
    has been difficult to achieve.
  • Research is ongoing on a Stirling cycle MEMS
    cooler being developed in NASA Glenn.

(Moran,2001)
50
Microscale VCRs
  • The Stirling Cycle is much like the vapor
    compression cycle and is shown below.

(Moran,2001)
51
Microscale VCRs
  • Using diaphragms instead of pistons, the MEMS
    Stirling cooler is fabricated with semiconductor
    processing techniques to provide a device with
    planar geometry.
  • The result is a flat cold surface for extracting
    heat and an opposing flat hot surface for thermal
    dissipation. A typical device would be composed
    of numerous such cells arranged in parallel
    and/or series with all layers joined at the
    periphery of the device to hermetically seal the
    working gas.

(Moran,2001)
52
Microscale VCRs
(Moran,2001)
53
Microscale VCRs
  • The expansion and compression diaphragms are the
    only moving parts.
  • Expansion of the working gas directly beneath the
    expansion diaphragm in each cycle creates a cold
    top end for extracting heat, while compression at
    the other bottom end creates a hot region for
    dissipating heat.

(Moran, 2001)
54
References
  • Cengel and Boles, 2002, Yunus A., Boles, Michael
    A. (2002). Thermodynamics an Engineering
    Approach. New York NY McGraw-Hill.
  • Chiriac, Florea Chiriac, Victor (2005). An
    alternative Method for the Cooling of Power
    Microelectronics Using Classical Refrigeration.
    ASME/Pacific Rim Technical Conference and
    Exhibition on Integration and Packaging of MEMS,
    NEMS, and Electronic Systems Advances in
    Electronic Packaging. pp 425-430.
  • Heydari, Ali. (2002). Miniature Vapor Compression
    Refrigeration System for Active Cooling of High
    Performance Computers. 8th Intersociety
    Conference on Thermal and Thermommechanical
    phenomena in Electronic Systems. pp. 371-378.
  • IEEE Standard Dictionary of Electrical and
    Electronics Terms. (1973). New york
    Wiley-Interscience.
  • Moran, Mathew E. (2001). Micro-Scale Avionics
    Thermal Management. 34th International Symposium
    on Microelectronics sponsored by the
    International Microelectronics and Packaging
    Society.
  • Peeples, John. W.(2001). Mechanically Assisted
    Cooling for High Performance Applications.
    Advances in Electronics Packaging Procedings of
    the Joint ASME/JSME Conference on Electronics
    Packaging. Pp. 899-904.
  • Phelan, Patrick Chiriac, Florea Chiriac,
    Victor (2004). Designing a Mesoscale
    Vapor-Compression Refrigerator for Cooling
    High-Power Microelectronics. Intersociety
    Conference on Thermal Phenomena, 1, pp. 218-223.
  • Schmidt, Roger R., and Notohardjono, Budy D.
    (2002). High-End Server Low-Temperature Cooling.
    IBM Journal of Research and Development, 46 (
    6), pp. 739-750.
  • Wikipedia the Free Encyclopedia (August 2006).
    CMOS. Retrieved August 2006. http//en.wikipedia.o
    rg/wiki/CMOS .
  • Wikipedia the Free Encyclopedia (August 2006).
    Electron mobility. Retrieved August 2006.
    http//en.wikipedia.org/wiki/Electron_mobility
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