Intel Intel E7230 MCH, Thermal/Mechanical Design Manual

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Intel
®
E7230 Chipset Memory Controller Hub (MCH)
Thermal/Mechanical Design Guide 17
5
Thermal Metrology
The system designer must make temperature measurements to accurately determine the thermal
performance of the system. Intel has established guidelines for proper techniques to measure the
MCH die temperatures.
Section 5.1 provides guidelines on how to accurately measure the MCH
die temperatures. Section 5.2 contains information on running an application program that will
emulate anticipated maximum thermal design power. The flowchart in Figure 5-1 offers useful
guidelines for thermal performance and evaluation.
5.1 Die Temperature Measurements
To ensure functionality and reliability, the T
case
of the MCH must be maintained at or between the
maximum/minimum operating range of the temperature specification as noted in Table 3-1 . The
surface temperature at the geometric center of the die corresponds to T
case
. Measuring T
case
requires special care to ensure an accurate temperature measurement.
Temperature differences between the temperature of a surface and the surrounding local ambient
air can introduce errors in the measurements. The measurement errors could be due to a poor
thermal contact between the thermocouple junction and the surface of the package, heat loss by
radiation and/or convection, conduction through thermocouple leads, and/or contact between the
thermocouple cement and the heatsink base (if a heatsink is used). For maximize measurement
accuracy, only the 0° thermocouple attach approach is recommended.
5.1.1 Zero Degree Angle Attach Methodology
1. Mill a 3.3 mm (0.13 in.) diameter and 1.5 mm (0.06 in.) deep hole centered on the bottom of
the heatsink base.
2. Mill a 1.3 mm (0.05 in.) wide and 0.5 mm (0.02 in.) deep slot from the centered hole to one
edge of the heatsink. The slot should be parallel to the heatsink fins (see Figure 5-2 ).
3. Attach thermal interface material (TIM) to the bottom of the heatsink base.
4. Cut out portions of the TIM to make room for the thermocouple wire and bead. The cutouts
should match the slot and hole milled into the heatsink base.
5. Attach a 36 gauge or smaller calibrated K-type thermocouple bead or junction to the center of
the top surface of the die using a high thermal conductivity cement. During this step, ensure no
contact is present between the thermocouple cement and the heatsink base because any contact
will affect the thermocouple reading.
It is critical that the thermocouple bead makes
contact with the die (see Figure 5-3 ).
6. Attach heatsink assembly to the MCH and route thermocouple wires out through the milled
slot.