Dear Lasmux,
have you considered printing the enclosure from conductive ABS ?
Kind Regards,
rudi
I did consider a conductive enclosure. I didn't go for this as I was concerned about increased capacitive coupling to ground on the signal pin, which would negatively affect the return loss on probed lines. I really want to keep that 0.7pF input capacitance, which was very difficult to achieve.
Another issue is that the enclosure is a very small print, and it has to interface with a real PCB. When I was prototyping I found that if the print wasn't dimensionally accurate enough, the PCB just wouldn't fit, especially around the probe tip socket area. Conductive ABS is normally printed via an FDM process which doesn't have the precision needed. Not to mention that FDM prints don't look as aesthetically pleasing as SLS prints.
I did consider a conductive enclosure. I didn't go for this as I was concerned about increased capacitive coupling to ground on the signal pin, which would negatively affect the return loss on probed lines. I really want to keep that 0.7pF input capacitance, which was very difficult to achieve.
Another issue is that the enclosure is a very small print, and it has to interface with a real PCB. When I was prototyping I found that if the print wasn't dimensionally accurate enough, the PCB just wouldn't fit, especially around the probe tip socket area. Conductive ABS is normally printed via an FDM process which doesn't have the precision needed. Not to mention that FDM prints don't look as aesthetically pleasing as SLS prints.
Ignorant suggeston: could you use a conductive paint? I assume you could mask off the areas where you want to keep capacitance low.
I've no idea about how well paint would or wouldn't adhere to the plastic, but it would be in the protected interior. The sintered nylon I've used is relatively rough (compared to SLA!), which might help.
I did consider a conductive enclosure. I didn't go for this as I was concerned about increased capacitive coupling to ground on the signal pin, which would negatively affect the return loss on probed lines. I really want to keep that 0.7pF input capacitance, which was very difficult to achieve.
Another issue is that the enclosure is a very small print, and it has to interface with a real PCB. When I was prototyping I found that if the print wasn't dimensionally accurate enough, the PCB just wouldn't fit, especially around the probe tip socket area. Conductive ABS is normally printed via an FDM process which doesn't have the precision needed. Not to mention that FDM prints don't look as aesthetically pleasing as SLS prints.
Ignorant suggeston: could you use a conductive paint? I assume you could mask off the areas where you want to keep capacitance low.
I've no idea about how well paint would or wouldn't adhere to the plastic, but it would be in the protected interior. The sintered nylon I've used is relatively rough (compared to SLA!), which might help.
That could work tbh. The coating would have to be on the outside though as the enclosure at the front of the probe is not split into two (it's in one part) so you couldn't mask off the area near the front of the probe which is most susceptible to noise. As it's on the outside it would need to be reasonably aesthetically pleasing when applied. I've never tried to spray paint 3D printed parts before though. It sounds... time consuming...
I did consider a conductive enclosure. I didn't go for this as I was concerned about increased capacitive coupling to ground on the signal pin, which would negatively affect the return loss on probed lines. I really want to keep that 0.7pF input capacitance, which was very difficult to achieve.
Another issue is that the enclosure is a very small print, and it has to interface with a real PCB. When I was prototyping I found that if the print wasn't dimensionally accurate enough, the PCB just wouldn't fit, especially around the probe tip socket area. Conductive ABS is normally printed via an FDM process which doesn't have the precision needed. Not to mention that FDM prints don't look as aesthetically pleasing as SLS prints.
Ignorant suggeston: could you use a conductive paint? I assume you could mask off the areas where you want to keep capacitance low.
I've no idea about how well paint would or wouldn't adhere to the plastic, but it would be in the protected interior. The sintered nylon I've used is relatively rough (compared to SLA!), which might help.
That could work tbh. The coating would have to be on the outside though as the enclosure at the front of the probe is not split into two (it's in one part) so you couldn't mask off the area near the front of the probe which is most susceptible to noise. As it's on the outside it would need to be reasonably aesthetically pleasing when applied. I've never tried to spray paint 3D printed parts before though. It sounds... time consuming...
I'm presuming you don't want anything conductive near the tip, but you do want a conductive shield away from the tip. I'm also presuming that, say, a 90%/0% coverage in the right/wrong places is better than a 0%/0% coverage, so "missed" coverage isn't too critical.
Hence, could you insert a plug, possibly 3D printed to the right shape, then (spray) paint the interior, then remove the plug? I have no advice about making contact between the paint and the circuit board.
There is also conductive silver-plated copper heatshrink
https://ph.parker.com/us/en/series/electrically-conductive-heat-shrinkable-tubing.
There are also microwave absorbent foams, designed to minimise cross-coupling and cavity resonance
https://ph.parker.com/us/en/series/microwave-absorber-materialsFor the avoidance of doubt, I am not recommending Parker; they are simply the first products I came across
![Smiley :)](https://www.eevblog.com/forum/Smileys/default/smiley.gif)
They also do conductive paints and epoxy.
@joeqsmith
Thanks, that's very intereting!
I'm presuming you don't want anything conductive near the tip, but you do want a conductive shield away from the tip. I'm also presuming that, say, a 90%/0% coverage in the right/wrong places is better than a 0%/0% coverage, so "missed" coverage isn't too critical.
Yes exactly. The important thing is to keep the copper away from the signal tip and the first ~1cm of the probe body. This also applied to the PCB layouy. There are parts of the PCB where there is no ground plane under the signal traces to reduce ground coupling.
Hence, could you insert a plug, possibly 3D printed to the right shape, then (spray) paint the interior, then remove the plug? I have no advice about making contact between the paint and the circuit board.
There is also conductive silver-plated copper heatshrink https://ph.parker.com/us/en/series/electrically-conductive-heat-shrinkable-tubing.
Possibly could use a plug. On reflection, I think a spray solution will be too difficult to implement reliably, without also ensuring there's no conductive paint that accidentally finds itself in the wrong place. I think I'd have to spray directly into the 'cavity' where the plug is, and the pressure of the spray may allow paint to get where it shouldn't be, despite the plug. I might also look into a paint 'dip', where I can dip the back end of the enclosure to a controlled dip. Interesting about the conductive heatshrink.
@joeqsmith
Thanks, that's very intereting!
I'm presuming you don't want anything conductive near the tip, but you do want a conductive shield away from the tip. I'm also presuming that, say, a 90%/0% coverage in the right/wrong places is better than a 0%/0% coverage, so "missed" coverage isn't too critical.
Yes exactly. The important thing is to keep the copper away from the signal tip and the first ~1cm of the probe body. This also applied to the PCB layouy. There are parts of the PCB where there is no ground plane under the signal traces to reduce ground coupling.
Hence, could you insert a plug, possibly 3D printed to the right shape, then (spray) paint the interior, then remove the plug? I have no advice about making contact between the paint and the circuit board.
There is also conductive silver-plated copper heatshrink https://ph.parker.com/us/en/series/electrically-conductive-heat-shrinkable-tubing.
Possibly could use a plug. On reflection, I think a spray solution will be too difficult to implement reliably, without also ensuring there's no conductive paint that accidentally finds itself in the wrong place. I think I'd have to spray directly into the 'cavity' where the plug is, and the pressure of the spray may allow paint to get where it shouldn't be, despite the plug. I might also look into a paint 'dip', where I can dip the back end of the enclosure to a controlled dip. Interesting about the conductive heatshrink.
All valid concerns, of course.
The design of the plug would be critical, of course. Would something like cotton wool be sufficient?
I'm sure there are conductive paints, so it may be possible to just coat part of the interior with a brush rather than a spray. A little
mechanical experimentation is in order
![Wink ;)](https://www.eevblog.com/forum/Smileys/default/wink.gif)
Can I suggest starting a separate topic on the subject? I'm sure many people here have experience with generic EMI/EMC mitigation techniques/technology - and they may not be following a long thread about a scope probe.
Conductive paints are a gamble. You can do them with a brush instead of a spray, which is better, but... still a crapshoot. Many conductive paints require multiple coats to get any real conductivity. They also require specific conditions to apply them, and usually require 24 hours between coats, also depending on climate conditions. It's a lot of work and likely some headaches that may or may not pay off at all. Even if you get it good at first, the paint can eventually flake off and lose it's conductivity as it ages. It might still be better than nothing, but the labor involved doesn't seem like it's worth it to me.
If conductive heat shrink would work, I would try that first. If it works, cool.
@joeqsmith
Thanks, that's very intereting!
I'm presuming you don't want anything conductive near the tip, but you do want a conductive shield away from the tip. I'm also presuming that, say, a 90%/0% coverage in the right/wrong places is better than a 0%/0% coverage, so "missed" coverage isn't too critical.
Yes exactly. The important thing is to keep the copper away from the signal tip and the first ~1cm of the probe body. This also applied to the PCB layouy. There are parts of the PCB where there is no ground plane under the signal traces to reduce ground coupling.
If you look at the design of the N2795, there is a hard plastic part and a soft silicone rubberized part, where the MK1 bionic grabber is supposed to handle the probe. I'm going to guess that this part is shielded for sure.