I just tested the heat gun in a formal experiment. I'm too tired to post a full write-up, so here's a summary of my lab notes:
Heat Gun: Steinel HL2010E (not recommended)
Temperature Setting: 800*F
Airflow setting: LOW
Nozzle: 75mm "Spreader Nozzle"
Distance from nozzle to work surface: 1.0"
Method of temperature measurement: thermocouple (i.e. a kitchen thermometer, with the probe laid flat on the work surface directly below the nozzle output)
TIME TEMP (*C)
T=0 24.9
T+30 86.6 <-- The gun reached 800*F at exactly 30 secs
T+60 142.8
T+90 169.1
T+2min 178.6
T+2.5 187.3
T+3min 193.2
T+3.5 205.9
T+4min 210.8
T+4.5 212.6
T+5min 213.9
T+5.5 215.1
T+6min 216.7
T+6.5 218.3
T+7min 218.5
T+7.5 222.1
T+8min 220.3
T+8.5 219.6
T+9min 220.4
T+10min 219.1
As you can see, it's a pretty good reflow profile. Starts to reflow after 2 to 2.5 minutes, and peaks at ~210*C after 4 minutes. Leaving it on for a full 10 mins only adds a few more degrees beyond that. At the 10 min mark, I switched the gun to "cool down" mode, and it took 2 mins 10 secs to cool all the way back to 120*F.
I would like to amend my previous post btw; 850*F is a bit too high. I tried it and it melted the white plastic SMD connectors on the board before it melted the solder. Dropping the temp to 800*F worked perfectly, and the plastic never melted/singed/discolored again.
Hopefully this clears up once for all the myth about cooking/scorching/incinerating/vaporizing IC's with 450*C heat guns.
I apologize that I am quoting this in length, but it's needed for context.
So, I am experimenting with various "ghetto reflow" techniques recently, including semi reflow with a heat gun, and this post confuses me.
(My heatgun is similar to yours, it's a cheap 2000W one with two settings, low = 350C, and high is 550C)
I can't see why you need more than 3 minutes (!!) to even reach 200C. Further above you say even that you need to set your heat gun to 800F (425 deg C.) to be even able to melt anything. (Suggesting that anything below 800F wouldn't work). This contradicts all my own observations.
But then again, you may well be right, as you say somewhere "convection heat transfer is a bitch".
I used a thermocouple right above the chip, and it showed 210C, but of course this shows only the temperature of the hot air coming from the gun and is not an indication whether the PCB itself or whatever part actually has this temperature for "reflowing". Saying: It is *DARN DIFFICULT* to even assess the actual temperatures you're getting when you try a "reflow" with a heat gun. So even with a thermocouple to measure, I am still there where I was before.
If what you say is true that you need to set your H.G. to 450 deg C., then basically this means I can try "reflowing" at low (350 deg) until I am blue in the face, it won't ever reach the temp to actually do anything. (Now not considering that most of these "reflows" are in reality only fixing things by softening the underfill, which seems to be the actual problem in many cases)
Furthermore, I am confused why you use this odd spreader nozzle which basically spreads out into a thin line, so no surprise that moving the H.G. just a millimeter messes things up. Likewise, I'd consider this nozzle extremely impracticable if not impossible to "reflow", say a GPU chip. (How would you do this with this type of nozzle?).
Add: I see you're using a capillary thermo probe there, like those which are used in ovens. I am not a pro by a long-shot, but I wonder how accurately this would reflect the actual temps. I mean it's possible this is also not accurate (not better than the thermocouple) and/or that the setup is very "laggy" (as someone mentioned). It's just that the temps in your list and the times there to me make not much sense.
If I take what you say there as true, it would mean reflowing with a heat gun, if at all, would need MUCH higher temps, and a MUCH longer time, like 7-8 minutes at least until something even melts?
Regards
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