Is there something like Moore’s law with LED emitters?
I’ve refreshed many old lights with newer emitters and the increased output is amazing.
Will I look back on today’s emitters 10 years from now and laugh at how weak they are or has this technology been nearly pushed to its limit?
Not asking for crystal ball answers, just wondering if anyone has deep knowledge of how far this can go.
If the led is soldered onto a alumnium non-DTP board (this is what the Ultrafire C8 likely came with), yes probably it will cook. If the led is soldered onto a copper DTP-board (such as a Sinkpad, Noctigon or KD-DTP board) and is clamped down with some hermal compound in between, it will be fine.
With led technology, there is a theoretical limit of about 300 lumen/W for white leds (a bit more for green leds). We are now at over 200 lumen/W so for led efficiency at least Moore’s law certainly does not apply. But we may be able to stuff more and more power in a little volume and make ever so brighter leds, but they require ever more powerful batteries (and regarding Moore’s law and batteries: regardless of the chemistry you can only stuff so much energy in a volume before you are litterally producing bombs) . And with laser pumped phosfor light sources that are just now on the market that power/volume is rising again.
Overall I see exciting improvements ahead but also too many theoretical limits to believe that Moore’s law will apply on leds.
what is an alternative way to keep a 17mm driver in place? i have a cheap 18650 zoomable host and it keeps popping out. i have tried soldering it to the pill but no luck. it used to fit tight but not anymore.
If the pill is brass, you could try to solder it with lots of flux and a very hot solder iron, I have a 80W monster for that kind of work.
If the pill is aluminium, at two positions around the driver I solder a thin copper wire around the edge from ground ring to ground ring, if possible I try to start the wire inside a via. After soldering (I try to get the solder all around the edge) I file the edge to shape so that the driver is still just too large for the cavity in the pill, and the component-side-ground-ring filed back to almost flat. Then I solder all the ledwires and last the driver is pressed in the pill between a vice. The driver is then held in place by friction, and it has good electrical contact with ground.
If you don’t need an electrical connection between pill and driver (e. g. if the tube is pressing directly onto the driver when screwed in) you could also glue the driver to the pill with a small amount of Arctic Alumina or similar. Two tiny drops of glue at opposite positions is often sufficient.
Here is a question that I can’t find an answer to.
Immediately after a rechargeable Li-ion cell is manufactured, what is its voltage?
Is it zero?
Is it perhaps around 3.7v? If it is then charging it to 4.2V would be in a sense over volting it.
How could it be zero when first manufactured? If it is then they would have to have been charged to about 3.7 when shipped. If they are, then why is it that first initial 0V state not damaging to the cell?
I personally think they are manufactured at 3.7V and shipped. (no charging after manufacture)
Also, I have witnessed 10 year old NOS ( new old stock) cells resting those 10 years at 3.7V charging up and performing almost as good as new. Another question would be if a brand new cell was charged to 4.2V, then discharged to 3.7V and put aside for 10 years. Would it still charge up and perform as new , just as a NOS cell does?