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Constructing a Power Supply Cooler

*Time to complete project under an hour.

To complete this project you will need

-Some kind of powertool to help cut metal and drill holes

-Bolts to mount hardware

-Small screw driver philips or flathead depending on the bolts and screws you have

-Pliers to fasten hardware with bolts

-A case fan or cpu fan

-An adapter that changes the fan wire to that of the kind of powersupply wire you are using

-A basic powersupply from an old computer

-Rubber or foam pads for feet and spacers

-A steady hand when cutting metal

-Most of these fans operate at 12volts DC. For a fan power cable that uses 3pin fan mainboard cable such as certain fans from cpu coolers that connect to the motherboard, use 3pin fan to 4pin molex converter cable (the fan in the cooler used in the guide used a 3pin fan to 4pin molex connectionfan connection I used the 3pin to 4pin 12volt powersupply connector).

*Possible parts to purchase

-3pin fan to 4pin molex connector $1.99


-Hard Drive Cooler $6.99

*uses 4pin molex 12volt power supply connector


-Case Fan $2.99

*uses 4pin molez 12volt power supply connector


-Case Fan 2 $3.99

*uses 4pin molex 12volt powersupply connector


-Power Supply Power Cord $4.69


-Powersupply $9.99

*has 4 4pin molex 12volt power cables


-External 3 1/2inch hard drive enclosure $14.99

*12Volt PSU included would use 4pin molex (similar to one used in guide)



Pic 18 This shows the type of bolts I used. Note you can screw them together end to end. These are basic mounting bolts for a motherboard to sit on and bolt to.


Pic 12 This shows the pliers I used, the philips screw driver and the foam pads.


Pic 19 Shows the type of fan you can use with the proper power wire and a converter from standard power cord to that of a cpucase fan.


Pic 23 Shows a common cpu heatsink and fan combo common to hardware that's a little older. No one wants old computers all the better to get free spare parts from. If you can salvage an old system, even if it's just to utilize the old power supply and cpu or case fans then your already recycling and saving money.


Pic 5 Shows the inside of the external hard drive enclosure I chose to re-use for this project. The hard drive enclosure is displayed opened up andshowing how the hard drive sits inside case. Note the hard drive, it's a 3 1/2 inch drive connected with an ide drive cable.


Pic 14 Shows the holes made through top of the enclosure. The holes I made are just a little smaller than the thickness of a bic pen. A drill will work just fine here. It's up to you how many holes and their spacing. Though having giant holes will leave only enough room for a few holes and too much air will be directed only through the holes directly over the fan we will be installing instead of spreading over the entire surface of cooler and powersupply.


Pic 3 Shows the fan in place on the inside of the aluminum enclosure. The fan is faced so air is pulled into the aluminum enclosure. The large hole on the bottom of the enclosure matches up with the size of the inner guards of the fan so that inner circle encompassing the fan blade is the same size as the hole made in the bottom of the coolers chassis. I would trace a marker around the inside piece of the fan on to aluminum enclosure in order to accurately cut the right size hole. I used a dremel to cut the hole out. I found if you hold the dremel with two hands and find a way to secure enclosure from moving, that short but firm traces over the marked circle is usually accurate enough to cut. If you try to go fast or have the dremel on to fast it makes it harder to cut and you tend to bounce and skim the surface. Also if a dremel is not available but a drill is you can use the same theory but hold tighter on drill, go slower and I would even make sure the drill bit is in the drill as far as possible so when your pressing on drill bit side ways it don't break and you have more control over where it goes. Note the 4 bolts sticking out of the chassis. Mark the holes using the fan as a guide and drill the holes needed to mount the fan on the inside over the large hole on bottom of enclosure.


Pic 7 This is a picture of the need to hold the inside nut in place with small pliers while tightening the outside bolt to mount fan.


Pic 8 This is what it should look like inside when you've mounted fan over fan hole you made earlier.


Pic 13 Another shot of the end cap off of chassis and fan mounted over fan hole on inside of enclosure.


Pic4 You can see another angle of the bottom of the unit. I used a basic foam rubber pad found in shipping packaging as feet and as a spacer between cooler and power supply. The plastic end cap is also visible from this angle.


Pic 16 Here you can see the finished unit plugged in with it's own ac adapter like power supply... the one original to the hard drive enclosure.


Pic 24 Shows the unit ready for action plugged in and turned on.

Testing the units ability to cool a overheating mobile powersupply


Pic 1 Screen shot before starting a test to show the powersupply heating up under a non-stock tdp of 98 and dells stock tdc of 62 with Throttle Stop. using Intel Burn test in 8 thread mode with maximum available memory to fully load all 4 cores of the 920XM, I took this screen shot showing what settings will be used for the duration of this demonstration. Note also Throttle Stop is on and chip-set clock modulation is set to 100% with the multiplier set to turbo so to prevent thermal and power throttling and maintain highest dynamic turbo frequency possible for a given moments temperature and power draw. If the previous mentioned settings allow the processor to run out of spec beyond it's thermal and power limits, which I will show raises the powersupply's temperature (with the powersupply flat on the table like most users place them) well beyond idle temperatures, average and heavy load temperatures for a laptop's AC/DC power-supply adapter. This could lower the life expectancy of any electronic device.


Pic 9 8:28pm, idle on desktop for 10 minutes @ 101-102 degrees Farenheit. The temps are being recorded by taping the contact point of a thermal wire coming from a volt-meter set in thermal mode on Farenheit. As a way to determine the validity of these temperatures, the temperature read for the room by not touching the contact wire to any surface at all (at the moment) read 80 degrees farenheit which is fairly accurate being that the ambient temperture in my computer room is about 78 on average unless I block my heat vent in my room. See temperature in picture below.


Pic 20

8:29PM I started IBT, immediately after launching I decided to adjust the TDP to 130 and TDC to 110 because I didn't see high enough frequencies to truly push the PS. Since the graphics weren't being stressed at the same time this was my way of exceeding the powersupplys's normal thermal and power specification. I set 100 tests to ensure IBT wouldn't finish or stop stressing the processor before my testing was done.

8:53PM 112 degrees has been reached so far.


Pic 21 Temps are 114 degrees and continue rising.


Pic 2 9:53PM 115 degrees is reached and maintained. That's 3 degrees higher than the powersupply was 1 hour before. With IBT still pressing on I decide to wait a little longer to watch if there is anymore increases in temperature.


Pic 6 Screenshot of Intel Burn Test continuing to stress the processor 9:54 pm while waiting to utilize cooler for second half of test.


Pic 11 10:01 pm with the power-supply still maintaining a temperature of 115 degrees I place the power-supply on the cooler off of the table where it had been sitting as designed on it's feet.


Pic 17 Immediately the temperature readout lowers by 1 degree to 114.

10:03 pm just 2 minutes later and still under maximum load from IBT the temperature reads as 112 degrees.

10:29 only 28 minutes after placing the power-supply on the cooler the temperature has dropped by 14 degrees from the 115 degrees to 101 degrees still under 100% load since 8:29. Nearly a hour and a half of building heat and stress the cooler has already managed the heat that is in excess of the idle temperature that came from IBT in only 28 minutes of using the cooler. Amazingly the cooler returns temperatures to the the idle temps recorded when we started, which were 101 to 102 degrees with Intel Burn Test still running 100%. I press on.


Pic 15 12:29 Intel Burn Test is still running 100% and temperature still dropped lower than idle temps with no cooler. At 98 degrees there has been a total drop under 100% load of 17 degrees over 4 hours of IBT running at 100% cpu usage about 2 1/2 hours of which the cooler had been utilized. After recording temperatures I proceeded to end the Intel Burn Test run.


Pic 10 I recorded 88 degrees about 20 minutes after ending the Intel Burn Test run. 14 degrees lower than the 102 degrees idle temps without cooler.


Video This video shows the cooler plugged in and running.


*You could also use sheet metal cut to the length of the power supply. The width will need to be about double the width of the powersupply plus about 2 inches for the height (that's 1 inch for each side and an extra inch to overlap ends). Drill extra 4 holes through top along seam where you would overlap the sheet metal about 1 inch. I would clamp the piece in place before drilling or mark out both ends and drill while the sheet is flat. Use small bolts and nuts to fasten the sheet metal together into an enclosure shaped like the the hard drive enclosue I used to make my cooler. Take the enclosure and shove it into a larger piece of styrofoam. Pull out the enclosure and cut out the rest of the styro-foam piece, use this piece to insert into the end of enclosure as a cap for your enclosure. Maybe tape end up firmly to make a good seal for air pressure. Repeat for other side except you'll need to make a slit in styro foam to stick your wires through on the other side. Drill holes on side with seam and make a large hole as big as the size of your fans fan blades on the bottom like in the guide above. Follow the above instructions the same with this sheet-metal enclosure in place of the aluminum pre fabricated enclosure I used.

*You can buy a fish tank thermometer or any flat sticker-like thermometer and attach it to your power supply to keep track of your temperatures at a glance.

*Attach a heatsink from one of those sealed liquid cooled heatsinks you can buy with the included radiator and fan to your powersupply. Place radiator in a place that can vent the heat.

*Make a second unit to place on top of the powersupply (in addition to the first cooler unit) aiming down at the top. You can even utilize the same powersupply.

*Please I encourage everyone to get creative or atleast find a similar cooling solution. You can buy a hard drive cooler which is not quite the same design but would work the same way if used it to cool your powersupply. Please post your ideas and your own projects or solutions you find for your powersupply here for everyone to build ideas from.

*Depending on how many cables are available on the powersupply you use for the cooler you can plug in extra fans for an additonal cooling system for your laptop at the same time. This validates utilizing a seperate powersupply for your cooler. No waste here!

Edited by mw86

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Excellent job man, much appreciated and thanks for sharing your creation and your experience with us, could you make a rough estimate of the cost of the materials (considering that someone might have to buy everything) and the time it took you?

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Nice work and thanks for taking the time to do this write up! +1 rep.

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The information you requested has been added to the post. Glad you like it.

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Excellent job and great idea!

You should try old amd cooler. (Socket 939 without fan)

Thank you :) wow thats a great idea... it could probably draw even more heat out of the top surface of a notebook PSU. If I get spare time and I have spare parts around and could try to make a CPU Heatsink adaptation of this.

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