It's expensive, double to quadruple the price of the heat sink itself. It's an option though, just need a drawing.I would also think that @ HSUSA, you would be able to replicate the Rapid Led sink. They offer machine work now, so you could even offer up a custom pattern for machined holes.
I have no idea on price though.....
Any chance you've been able to run any tests on the 5.886 profile? Hungry minds and allCool setup @kamikaza , thanks for sharing that info
@Abiqua Back in the day I used 150cm²/W but the LEDs were about 26% efficient. 110cm²/W should be good for LED running at 35-40% efficiency. I am running my CXAs at 48% efficiency minimum and I use about 95cm²/W to get heatsink temps of 27C, almost as good as active cooled performance. So if you are running the Vero 10s at 37% typical, you could use anything from 90-110cm² depending on your goals.
@SupraSPLAny chance you've been able to run any tests on the 5.886 profile? Hungry minds and all
This is totally off topic to whatever you guys are talking about but would you guys know how important the heat sink is for this model of LED- http://au.mouser.com/ProductDetail/Cree-Inc/CXA3070-0000-000N00Z230F/?qs=sGAEpiMZZMu4Prknbu83y0bObCPMgyC/l6eQby5L/DGQDb9TViwpOg==
Sweet! That's exactly what I want to set up.Thanks to @foreverflyhi , I hope you don't mind I used your 5.88" module for this quick test
View attachment 3306793 View attachment 3306792
Ambient temp 23C
5.88" X 12" = 3120cm²
heatsink surface was flattened and polished to 1000 grit - Prolimatech PK3 paste
CXA3070 AB X 2 @ 1.45A = ~105W dissipation
30cm²/W
high RPM 140mm fan running at 5V (.123A * 4.9V = .6W)
heatsink temp stabilized at 27C
light lost to temp droop = ~3%
increased fan to 9V (.237A * 9.15V = 2.17W)
heatsink temp stabilized at 25.5
light lost to temp droop = ~2%
Can you do a simulate a fan failure? Or what do the heatsink temps look like if the fan isn't used?Thanks to @foreverflyhi , I hope you don't mind I used your 5.88" module for this quick test
View attachment 3306793 View attachment 3306792
Ambient temp 23C
5.88" X 12" = 3120cm²
heatsink surface was flattened and polished to 1000 grit -
CXAs mounted with Prolimatech PK3 paste
CXA3070 AB X 2 @ 1.45A = 105W dissipation
30cm²/W
high RPM 140mm fan running at 5V (.123A * 4.9V = .6W)
heatsink temp stabilized at 27C
light lost to temp droop = ~3%
increased fan to 9V (.237A * 9.15V = 2.17W)
heatsink temp stabilized at 25.5
light lost to temp droop = ~2%
Paste? That don't look like paste, looks like tape to meThanks to @foreverflyhi , I hope you don't mind I used your 5.88" module for this quick test
That's pretty impressive passive performance all things considered. No real danger of frying the cobs if the fan does fail. The CPU coolers tend to act like a solid block of aluminum without a fan.
How in the heck is that Fastech site searchable? http://www.fasttech.com/products/1612/10008079/1714800
one link at a time.
I had a similar idea and a pair of 5000K CXA3590s hanging around. Running them at 250mA and no temp droop to speak of, they are about 65% efficient or 210lm/W. The 5000K Vero 29 at 250mA should be about 58% efficient or 188lm/W. Awesome vegging lights! Cost is $5-$5.50 /PAR W, much less than I recently paid for my Oslon SSL deep reds LOL.
Thanks to @foreverflyhi , I hope you don't mind I used your 5.88" module for this quick test
View attachment 3306793 View attachment 3306792
Ambient temp 23C
5.88" X 12" = 3120cm²
heatsink surface was flattened and polished to 1000 grit - (this may not be worth the effort for large builds)
TIM = Prolimatech PK3 paste
CXA3070 AB X 2 @ 1.45A = 105W dissipation
30cm²/W
high RPM 140mm fan running at 5V (.123A * 4.9V = .6W)
heatsink temp stabilized at 27C
light lost to temp droop = ~3%
increased fan to 9V (.237A * 9.15V = 2.17W)
heatsink temp stabilized at 25.5C
light lost to temp droop = ~2%
passive cooled at 90cm²/W
heatsink temp ~31C
light loss to temp droop = 2.88%
passive cooled at 60cm²/W
heatsink temp ~33C
light loss to temp droop = 6.98%
passive cooled at 30cm²/W
heatsink temp ranges from 36-40C (may have gotten hotter with more time, but not much hotter)
light loss to temp droop = 8.29%
So if we call baseline efficiency of the COB 42%, this is how they stack up when we take the electrical consumption of the fan into account:
Active cooled 5V 30cm²/W = 40.56%
Active cooled 9V 30cm²/W = 40.2%
Passive 90cm²/W = 40.89%
Passive 60cm²/W = 39.16%
Passive 30cm²/W = 38.6%
Once again the 5V outperformed 9V (I should try 7.5V). The passive cooling numbers are impressive, confirming the results from the 10.08" profile (page 5), although 90cm²/W is an expensive proposition. In my test there was very little air movement and the heatsink was not in an optimal position for convection, so in practice I expect the passive cooling could have performed even better.
So what you're saying is I went overboard, no surprise its what I'm good at.
