Every once a while I see people asking which direction my fans should be going and here are some answers. Some of the displays required adobe flash player in order to view.
http://www.silverstonetek.com/tech/wh_positive.php?area
http://icrontic.com/articles/pc_airflow_heat_cooling_guide <<--Source
The parts and mod list
- AMK SX1000 PC Case
- ABIT KV7 Motherboard
- AMD 3200+ XP Processor
- 2 x 256 MB Corsair XMS DDR 400 Memory
- Enermax 465 PSU
- ATI 9700
PRO Video Card
- Zalman CNPS7000A Heatsink
- 60 GB Maxtor Hard Drive
- Rounded EIDE cables
- 2 x 80mm. front intake fans
- 2 x 80mm. rear exhaust fans
- 2 x 80mm. side intake fans
- 1 x 80mm. top blowhole
- WindowsXP
How the tests were conducted
Each test was conducted with a room temperature of 23.6 +/- 0.4 degrees Celsius. The system idled in its testing configuration for 30 minutes prior to Sisoft Sandra CPU burn-in (CPU Arithmetic Benchmark/CPU Multi-Media Benchmark) run 100% stress for 25 consecutive times. Motherboard Monitor 5.3.4.0 recorded the results at 5 second intervals. “Idle” temperature was determined by the consistent temperature reading for 20 measurements recorded prior to the burn test. “Time to idle” was determined by the amount of time in minutes and seconds from the last peak CPU temperature until the first reading of the “Idle” temperature.
Testing configurations
The basic AMK SX1000 case is a very common and popular PC case for enthusiasts under whatever manufacturer name it happens to be.
We installed matching 80mm. fans and drilled holes where fans weren’t meant to go. First two fans in the front.
Then two fans in the rear.
Then a top blowhole.
And finally two fans in the side.
With all fans in place it looks like quite a lot of cooling power.
We’ve always been preaching the golden words of cooling; “in through the front and out through the rear…or top”. This is the golden rule when it comes to all PC cases for air cooling no matter what components are inside.
But, having too much time on our hands, we questioned ourselves. After all we are the same people who came up with a 1700 CFM case and a ghetto duct made of cardboard. It only seemed appropriate that we journey down this road. We questioned ourselves as to the effectiveness of so many fans with so many conflicting airflow patterns. Could it be that more fans isn’t better? Could it be that the airflow may become quite a mess thus diminishing the overall effectiveness?
So we spent a few days looking at thermometers and watching a PC cook itself. 10 different configurations were tested in our quest to determine how airflow affects heat.
No fans
All fans
Rear only
Top only
Side only
Top and front
Top and side
Top and rear
Rear and side
Rear and front
A word to the wise
A PC case is essentially a box. It can be safely said that there is a consistency to ALL PC case configurations; processors, video cards and drives are generally in the same area. However the specific style of PC case and type of components varies greatly from user to user. These differences will affect your specific results. CPU temperatures may be higher or lower depending on type of heatsink and processor. Another extremely important variable for testing is ambient room temperature. The temperature of a room, warmer or colder, can greatly affect personal results. We’ve intended these tests to demonstrate the combination of fans and their effect on cooling. This may not be the rules set in stone for all but they will surprise you and give you food for thought.
The results
Surprised?
Conclusions
We would be lying if we weren’t. It was our assumption that the tests with ALL the fans in operation would produce the best results but it didn’t. Time to idle represents how effectively the configuration removes heat from the PC case. The shorter the time the better. CPU peak and idle as well as System peak and idle are easy to interpret. We would like to think that System temperature represents an average of how cool every component in a PC is.
- The top and rear exhaust produced the best CPU and System results but nearly placed last for time to idle. We tested three times for this result as we didn’t believe the first two.
- A single rear exhaust fan produces the best results overall. This flushes the theory of more is better right out the door.
- A top only or top and front combination places in the middle of the pack for CPU and System peak cooling BUT does whisk away the heat in a very short amount of time.
- Even with no cooling fans besides the heatink…heatsink size and type of fan can deliver good results.
So there you have it. A few theories dashed upon the rock perhaps. At least for this type of PC case and components. What should be taken away from this? Quite simply that more may not necessarily be better but, for us enthusiasts, more may be cool…for looks.
What is positive air pressure? |
Computer chassis are typically equipped with many case fans, some are designed for exhaust and others for intake. When intake fans’ combined airflow is greater than exhaust, a positive pressure is created inside the chassis. Conversely, when the airflow is greater for exhaust than it is for intake, a negative pressure is created.
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How does positive and negative pressure affect airflow in a chassis?
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The major difference between positive and negative pressure is the way vents and various gaps are affected. |
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This photo shows an example of a modern high performance chassis with extra vents not occupied by case fans. These vents can become either exhaust or intake depending on whether the chassis has positive or negative air pressure respectively. |
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*Dedicated vents aren’t the only places on a chassis that can act as pathways for airflow, gaps on the outside the chassis such as the one shown in this photo can also be affected. |
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The benefit of having positive air pressure:
Benefit 1: Dust reduction
Newer case models now sometimes include fan filters in an attempt to reduce dust build up inside the chassis. If the chassis has positive pressure, only intake fans require fan filters to effectively reduce dust build up.
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The diagrams show that chassis with positive air pressure can prevent dust from penetrating into the chassis by use of filters on intake fans and forcing air out of the chassis through unfiltered vents and gaps. On the other hand, a chassis with negative air pressure draws in air from unfiltered vents and gaps that even with fan filters placed on key intake fans, dust can penetrate into the chassis easily.
The idea to use positive air pressure in designing dust-proof chassis comes from the concept of a cleanroom. The cleanrooms are used often in Hi-tech, medical, and food processing industries. All cleanrooms, regardless of their levels and sizes, are built to maintain a positive pressure environment to prevent dust from entering the room.
Benefit 2: Maximize graphics card cooler’s efficiency
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| Left: Partially sealed graphics card cooler Right:Fully sealed graphics card cooler |
Currently, all original graphics card coolers (non-custom) are designed to exhaust air toward the rear to prevent heated air from being recycled back into the chassis:
Partially sealed graphics card cooler:
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| Diagram A:Heated air are blown partially out of the chassis with the rest remaining inside the chassis | |
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| Diagram A-1: |
In a negative pressure chassis, heated air that is suppose to be blown out will re-enter the chassis through openings nearby and raising the chassis temperature. | |
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| Diagram A-2: |
In a positive pressure chassis, all heated air from the graphics card will exit the chassis, keeping overall temperature low. | |
Fully sealed graphics card cooler:
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| Diagram B: |
Fully sealed graphics card does not exhaust heated air into the chassis, but the fan in the cooler is affected by the pressure inside the chassis. | |
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| Diagram B-1: |
In a negative pressure chassis, the air from outside will try to enter the chassis through all openings, including the graphics card exhaust opening. As a result, the fan in the graphics card cooler need to work harder to push the air out, becoming less efficient and likely to be more noisy. | |
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| Diagram B-2: |
In a positive pressure chassis, air will try to escape out of the chassis through all openings and exhaust fans. As a result, the fan in the graphics card cooler, which isdesigned to exhaust air out of the chassis, will work more efficiently with increased airflow and less noise.
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Q9650 @4.05Ghz 1.2125VID
Gigabyte P45 UD3P rev1.1
XFX GTX 260 Black Edition
HT Omega Claro Plus + Logitech Z-5500 + Energy 5.1 Speakers
