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Intel 200 User Manual

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Processor Thermal/Mechanical Information 
 
 
22  
 
Thermal and Mechanical Design Guidelines 
2.4 
System Thermal Solution Considerations  
2.4.1 
Chassis Thermal Design Capabilities 
The reference thermal solution for the Intel Celeron processor 200 sequence on the 
Intel Desktop Board D201GLY2 is a passive heatsink design, which requires chassis to 
deliver sufficient airflow cooling to ensure stability and reliability of processor.  The 
maximum allowable heatsink temperature (T
S-TOP-MAX
) is set to 91 °C for 
processor to ensure the capability of a chassis in providing sufficient airflow for 
processor cooling.  T
S-TOP-MAX
 is the maximum limit value for heatsink which is similar 
to T
CASE-MAX
 for lidded processors.  
The “usage power consumption” (P
CPU-USAGE
) of the Intel Celeron processor 200 
sequence was quantified at maximum of 16 W based on measurement done on Intel
®
 
Desktop Board D201GLY2 when tested with SYSMark04.  The reference thermal 
solution for processor is designed at P
CPU-USAGE
 for performance & cost optimal 
considerations.  Do not mistaken P
CPU-USAGE
 with processor’s TDP as documented in 
datasheet.  
Table 3.  System Thermal Solution Design Requirement  
1. 
System Thermal Solution Design Requirement 
Note 
3.  T
S-TOP-MAX  
≤ 91°C 
4.  
NOTE:   
1. 
Based on processor maximum Usage Power Consumption (P
USAGE
) of 16 W measured on 
Intel
®
 Desktop Board D201GLY2 when tested with SYSMark04.  
To evaluate the system thermal capability of a given chassis, the system designer is 
recommended to conduct in-chassis system thermal test.  The data to be collected are 
both processor power consumption (P
CPU
) and heatsink temperature (T
S-TOP
) with the 
above mentioned processor load at 35 °C external ambient condition.  The T
S-SYSTEM
 
can be estimated using Equation 1.  The thermal pass requirement for a given chassis 
can be met if T
S-SYSTEM 
≤ T
S-TOP-MAX
.  
Equation 1  T
S-SYSTEM 
= T
A
 + (T
S-TOP 
− T
A
× 16/P
CPU
 
≤ T
S-TOP-MAX 
= 91°C   
 
2.4.2 
Improving Chassis Thermal Performance 
The heat generated by components within the chassis must be removed to provide an 
adequate operating environment for the processor and all other components in the 
system.  Moving airflow through the chassis brings in fresh cool air from the external 
ambient environment and transports the heat generated by the processor and other 
system components out of the system.  Therefore, the number, size and relative 
position of fans and vents determine the chassis thermal performance, and the 
resulting ambient temperature around the processor.   
It is particularly important to choose a thermally advantaged chassis for the reference 
thermal solution for Intel Celeron processor 200 sequence on the Intel Desktop Board 
D201GLY2, which is a passive heatsink design.