Intel E6700 Mechanical Design Guidelines - Page 25

Thermal Metrology

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Thermal Metrology 3 Thermal Metrology This section discusses guidelines for testing thermal solutions, including measuring processor temperatures. In all cases, the thermal engineer must measure power dissipation and temperature to validate a thermal solution. To define the performance of a thermal solution the "thermal characterization parameter", Ψ ("psi") will be used. 3.1 Characterizing Cooling Performance Requirements The idea of a "thermal characterization parameter", Ψ ("psi"), is a convenient way to characterize the performance needed for the thermal solution and to compare thermal solutions in identical situations (same heat source and local ambient conditions). The thermal characterization parameter is calculated using total package power. Note: Heat transfer is a three-dimensional phenomenon that can rarely be accurately and easily modeled by a single resistance parameter like Ψ. The case-to-local ambient thermal characterization parameter value (ΨCA) is used as a measure of the thermal performance of the overall thermal solution that is attached to the processor package. It is defined by the following equation, and measured in units of °C/W: ΨCA = (TC - TA) / PD (Equation 1) Where: ΨCA = Case-to-local ambient thermal characterization parameter (°C/W) TC = Processor case temperature (°C) TA = Local ambient temperature in chassis at processor (°C) PD = Processor total power dissipation (W) (assumes all power dissipates through the IHS) The case-to-local ambient thermal characterization parameter of the processor, ΨCA, is comprised of ΨCS, the thermal interface material thermal characterization parameter, and of ΨSA, the sink-to-local ambient thermal characterization parameter: ΨCA = ΨCS + ΨSA (Equation 2) Where: ΨCS = Thermal characterization parameter of the thermal interface material (°C/W) ΨSA = Thermal characterization parameter from heatsink-to-local ambient (°C/W) ΨCS is strongly dependent on the thermal conductivity and thickness of the TIM between the heatsink and IHS. Thermal and Mechanical Design Guidelines 25

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Thermal Metrology
Thermal and Mechanical Design Guidelines
25
3
Thermal Metrology
This section discusses guidelines for testing thermal solutions, including measuring
processor temperatures. In all cases, the thermal engineer must measure power
dissipation and temperature to validate a thermal solution. To define the performance
of a thermal solution the “thermal characterization parameter”,
Ψ
(“psi”) will be used.
3.1
Characterizing Cooling Performance
Requirements
The idea of a “thermal characterization parameter”,
Ψ
(“psi”), is a convenient way to
characterize the performance needed for the thermal solution and to compare thermal
solutions in identical situations (same heat source and local ambient conditions). The
thermal characterization parameter is calculated using total package power.
Note:
Heat transfer is a three-dimensional phenomenon that can rarely be accurately and
easily modeled by a single resistance parameter like
Ψ
.
The case-to-local ambient thermal characterization parameter value (
Ψ
CA
) is used as a
measure of the thermal performance of the overall thermal solution that is attached to
the processor package. It is defined by the following equation, and measured in units
of °C/W:
Ψ
CA
= (T
C
– T
A
) / P
D
(Equation
1)
Where:
Ψ
CA
=
Case-to-local ambient thermal characterization parameter (°C/W)
T
C
=
Processor case temperature (°C)
T
A
=
Local ambient temperature in chassis at processor (°C)
P
D
=
Processor total power dissipation (W) (assumes all power dissipates
through the IHS)
The case-to-local ambient thermal characterization parameter of the processor,
Ψ
CA
, is
comprised of
Ψ
CS
, the thermal interface material thermal characterization parameter,
and of
Ψ
SA
, the sink-to-local ambient thermal characterization parameter:
Ψ
CA
=
Ψ
CS
+
Ψ
SA
(Equation 2)
Where:
Ψ
CS
= Thermal characterization parameter of the thermal interface material
(°C/W)
Ψ
SA
= Thermal characterization parameter from heatsink-to-local ambient
(°C/W)
Ψ
CS
is strongly dependent on the thermal conductivity and thickness of the TIM
between the heatsink and IHS.