Safe current for XML2 on Aluminum MCPCB

Okay, I did a quick test of my most-used FET light, the Astrolux C8. I’ve had it for about 1.5 years, and put on about 15-20 hours of “full output” usage on it (just a rough estimate). It does have a timed step-down, but I always bump it back up every time it steps down. So, it does get hot, though not too hot to hold.

The output is exactly what I tested on it when it was new, a little under 1300 lumens. No current measurements, though.

Okay, I know you say you can’t tell with FET lights, but if the damage is so quick, it’s got to show up as decreased lumen levels eventually. Unless the damage stops after a certain point, and lumen and current levels stabilize.

Is the damage you’re seeing, possibly due to improper heat-sinking?

Okay, from that chart, it looks like the damaging factor is heat at the junction point, not the amount of current flowing. Current plays some role, but it appears if you properly heat-sink things, most of damage is mitigated.

And even worst-case, it doesn’t seem the L70 lifetimes are affected much at all; just the L95 lifetimes.

I’m not sure if we can extrapolate accurately past Cree’s 3 amp testing, but if you’re right that 5A gives 500 hours until the LED is only 95% as bright, then that’s why I’m not seeing any drop at all after 15 or 20 hours.

I’m okay if I get 500 hours at almost “new” output levels. That would explain why people aren’t complaining.

Please check if you think my setup wasn’t cool the LED enough:

[Clemence]

Please check again, it’s the current that heavily affecting. Check those tests with the same tj but different current. Roughly 1A increase in current reduce the lifetime 4 times.

[Clemence]

Temperature of 55C with 2100mA current, L95 = 66,500 hours (or 54,400 in another set).
Temperature of 105C with 2100mA current, L95 = 14,900 hours.

Same current, different temperature, and the L95 is a third the value.

But, yeah, current also does hit the L95 values pretty hard too.

The L70 seems to be relatively unaffected by current, though.
45,400 hours with 1.5 amps. 36,300 hours with 3.0 amps.

Also, based on how those values jump around on that chart, I’m betting there’s a huge margin of error.

Think of it like this… On a macro scale, a light with lousy thermal path doesn’t even get very warm to the touch, yet the LED is screaming because it’s pretty much on fire. Cold outside air, etc., keeps the body of the light cool, yet the LED still screams in searing pain.

Same thing on a micro scale. The LED can be cooled from the bottom (Al or Cu, doesn’t matter) as much as you want, but the current density inside the chip still cooks it from the inside as well.

That’s why an LED that isn’t reflowed well to its star has a lousy thermal path and can go blue and die with much less current than one that’s reflowed perfectly.

And yeah, those figures for θJA are made up of a whole bunch of “partial” θs. First one’s from junction to the chip’s substrate or something.

+1
This is exactly what I wanted to say earlier. It’s the thermal bottleneck “above” the Aluminum Nitride substrate. Every material with thickness has thermal impedance/resistance. With every resistance there is heat build up. Don’t forget that the current flow inside the chip also face resistance.

[Clemence]

I get that, and I don’t disagree with the later stats you posted. But they seem to contradict your earlier statements, where you claim that the LED is damaged in just seconds at moderate over-driving, and you can measure that effect.

I’m not at all surprised that a modestly over-driven LED might show a 5% decrease in output after 500 hours of use.

What I was surprised at was your assertion that it happens in just seconds, even with your good heat-sink.

So, I’m not sure what your belief is now. Is it seconds, or hundreds of hours?

Seconds. It’s like 10 seconds, less with fragile E21A
EDIT: My rule is to never get past 1,5x rated max current.

[Clemence]

Okay, but you later said,

That seems to say 500 hours when driven at 5A (1.66x rated max current). Or are you saying that the full 5% damage gets done in the first 10 seconds, then almost nothing after that?

Are we talking about the same LEDs? I thought this was about Cree LEDs, like the XML or XPL. What current are you using to do significant damage in 10 seconds? It’s got to be way more than 5A. If you’re trying to shove 8 or 9 amps into the LED, then I can totally believe 10 seconds. But if it’s 5 amps, I don’t think Cree’s LM80 stats or personal usage of high-output lights backs that up.

Yeah, let’s be careful about what the datasheets says.

The LEDs are probably tested on non DTP MCPCBs, or high performance aluminium MCPCBs.

The type of MCPCBs we use transfer heat much more effectively to the body, meaning the LED is probably running much cooler under load vs on an aluminium MCPCB.

And most of our lights can’t overdrive LEDs for very long because of thermal control.

That 500 hours was my guesstimation derived from Cree’s LM80 data. But Cree never published anything above 3A - their max rated current.

I tested below LEDs:

- Nichia: 219C, 319A, E21A, 144AM/AR, 757GRV3, E17A

- Cree: XPL, XPL-HI, XPG, XTE, XPG2, XPE2, XHP50, (sorry, no XML or XML2)

- Some Citizen COB

  • Some unknown LED bulb LEDs

Cree is tougher than other LED I tested, but still suffer invisible damage (output reduction) at above 1,5 - 2x rated current. Whenever I get past max rated current, whenever I redo the output test, the voltage always reduced. The farther away from max rated current, the lower the voltage became. Lower forward voltage is a clear sign that output has permanently reduced. My test requires me to keep the LED at certain current for almost 2 minutes in each increment. I only write down the output after the voltage has stabilized. LED Vf is a very accurate good thermal sensor.
But as I said earlier, I sometimes forgot or skipped something and made me step backwards. Whenever I did this above max rated current, the voltage always permanently reduced. Even if I just stayed at the higher current step for few seconds

[Clemence]

I have never done specific tests for this, so what I know is some peculiarities that many leds showed that I tested.

1) after a led test (that usually goes well beyond specifications), in cases that they did not seem to have damaged the led, I often go back to a reasonable current within specs and let the led stabilise at that current. The output is always a bit (often just 1 or 2%, nothing serious usually) lower than the initial output at that current, and the voltage has dropped a bit. If I increase the current a bit to get back to the voltage that I originally measured, the output is exactly what I originally measured with non-increased current (so after overdriving the output seems to “follow” the voltage rather than the current). Of course now the output per Watt has suffered a bit.

2) there seems to be a recovery of the led over a longer period than a few minutes. Not just with bare leds but also with output/throw measurements of flashlights, I noticed several times that a re-measurement after a couple of minutes always gives a lower result, even when the light was fully cooled down, but when waited a day the measurement was back up again at the first value.

But as I said, this is all circumstantial observations that I gathered over time without specific testing for it, Clemence has already done more proper testing on this than I.

You can do some real quantitative testing specificially looking for the effects and get much more information, about how partial this recovery is for instance.

Has anyone ever done a long term lumen maintenance test on an LED? Something like running an XP-L HI at 5A (typical DD current) for a few hours or days to see how it holds up.

Interesting stuff. 1% or 2% doesn’t sound too bad, if you were driving things really hard to test failure currents. Strange about the long-term recovery of the LED, though. I would have thought if it didn’t recover within a few minutes, it wouldn’t. I presume it wasn’t just the battery recovery you were using.

Well, as I mentioned earlier, I re-tested a Astrolux C8 (FET driver with Samsung 30Q) that I’ve used for about 15-20 hours on max output over the past year-and-a-half. It gave the same output as when it was new.

However, my measurements are much less accurate than the 1% or 2% that djozz was talking about. And I’m not sure how much output variance clemence was seeing.

With the abundance of high quality copper MCPCB’s, my question is

Now are these boards comparable like Noctigon or KD for hold high Current and quality finiture?

I have checked quite a few DTP boards over time and they perform close to each other, and are at least all thermally way better than non-DTP boards.

Good to say Djozz,I hope also they will be perfect flat
without imperfections especially on the edges
where I found stairs on alu board time ago,had sanded