I've been across everything since April, and was aware of the issues.
Tried ordering directly from Pace last week, but the price comes up as $0.00
That's a bargain!
But USD$280 for freight to Australia?
Don't think so!
:-(
LOL ... yes, we just put the ADS200 webpage up last week, so we may not have entered the pricing at that time. It's up now though. Concerning the $280 shipping, I think you might consider purchasing through our Australian distributor Mektronics as we are restricted as to how we can ship overseas (only Fedex and UPS, I believe). This is because we sell direct as a convenience to the customer but we much prefer you buy through an authorized distributor. So you'll probably get a better shipping deal from Mektronics:
MEKTRONICS Australia
Website:
www.mektronics.com.auEmail: sales@mektronics.com.au
Aaron
The other question I have as well is how do we know we are comparing apples to apples - setting two units to 270 could mean two entirely different things depending on the way they regulate temperature. One unit might consider 270 the average temperature with temps going higher than that and the other unit might consider 270 the maximum temperature and it tolerates being pulled down below that, but is designed to not go much above it so its average is actually lower than what it is set for. How could one test for tip temp during use to get a graph of actual performance - that would be the final word i would think!
Aaron, does Pace have any comment on the low-temp test? I'm wondering if this is firmware fixable or a hardware issue.
I'm guessing we won't hear anything for a bit until they get their ducks in a row. It looks like I pulled the trigger too early buying a unit. Tequipment just shipped the ISB, so I'm probably going to eat the shipping costs and return it.
Aaron, does Pace have any comment on the low-temp test? I'm wondering if this is firmware fixable or a hardware issue.
I'm guessing we won't hear anything for a bit until they get their ducks in a row. It looks like I pulled the trigger too early buying a unit. Tequipment just shipped the ISB, so I'm probably going to eat the shipping costs and return it.
If their firmware is like their TO-220 placement, you guys are in trouble. The amount of time this is taking you'd think they're trying to install a web browser in there. It's a soldering iron. That's their main product.
The other question I have as well is how do we know we are comparing apples to apples - setting two units to 270 could mean two entirely different things depending on the way they regulate temperature. One unit might consider 270 the average temperature with temps going higher than that and the other unit might consider 270 the maximum temperature and it tolerates being pulled down below that, but is designed to not go much above it so its average is actually lower than what it is set for. How could one test for tip temp during use to get a graph of actual performance - that would be the final word i would think!
Marco Reps' review suggested the sensor may be further away from the tip, so this may explain the pace (no pun intended) at which they decided to recover in software. He noted no overshoots, just moderate and accurate recovery. Perhaps Pace could offer a menu option for aggressive thermal management, but that could end-up decreasing the famous life of the Pace tip-cladding.. Indeed, it does seem like apples and oranges, but firmware in part, may be able to flatten the user experience.
*edit: Added Marco Reps tip cutaway angles (still doesn't explain why competitors tips cost so much and don't last..)
Aaron, does Pace have any comment on the low-temp test? I'm wondering if this is firmware fixable or a hardware issue.
I've sent the video to our Engineers for review. We've done performance tests against competitive units and fared excellently in most cases. But note that it was never our intention to design a "JBC Killer" ... we just wanted to produce a solid, low cost, reliable soldering station that could be purchased by everyday technicians, yet withstand the rigors of intense production soldering, without costing an arm and a leg. As Dave mentioned in his review, perhaps a better comparison would be against the Hakko 951. From a cost of ownership basis, JBC is double the price for the initial cost and
more than double the price of our tips, so we need to have realistic expectations. We will be successful in 90-95% of the applications, and against the competition, even JBC, in standard applications. As shown in the video, our build quality is second to none and is designed to last 10-20 years, typical for a PACE Station. Our new TD-200 handpiece is superior to the JBC, Hakko Metcal, et al: tip-to-grip is excellent (the shorter the tip-to-grip, the better fine control, especially under a microscope), ergonomics are great, and our new Cool Touch technology works! Ask Dave about the temperature of the JBC handle at higher temperatures and I think you'll find it gets extremely hot in any extended use situation - JBC now ships the handle with a large foam grip to lessen the heat issue, but I believe it ruins the otherwise solid ergonomics of the JBC iron. All in all, the feedback we've received from recent customers has been overwhelmingly positive and I think you should all give the ADS200 a try!
Marco Reps' review suggested the sensor may be further away from the tip, so this may explain the pace (no pun intended) at which they decided to recover in software. He noted no overshoots, just moderate and accurate recovery. Perhaps Pace could offer a menu option for aggressive thermal management, but that could end-up decreasing the famous life of the Pace tip-cladding.. Indeed, it does seem like apples and oranges, but firmware in part, may be able to flatten the user experience.
Cliff,
You are correct about the placement of the sensor. JBC's is minutely closer to the front end of the tip, allowing for a slightly faster recovery, but it ends up costing you big bucks as they are super expensive to manufacture this way. Again, we are not trying to "beat" JBC, we are simply trying to provide a high-performance (despite Dave's comparison, the ADS200
is powerful) and affordable soldering station.
Aaron
Our new TD-200 handpiece is superior to the JBC, Hakko Metcal, et al: tip-to-grip is excellent (the shorter the tip-to-grip, the better fine control, especially under a microscope), ergonomics are great
Very true! The moment i tried the handpiece at a tech show i instantly knew that. JBC iron is far from that comfy feeling in your hand.
All in all i think the hardware is capable. the firmware should be able to address the noted deficiencies. But there should be a way to update the firmware by the user.
Three more things to add.
I do agree that you can't judge a product against one that is twice its price, well at least not often. There is sometimes that upset where a product half the price performs as well in every way, but it is probably more reasonable to be pleased if a product performs as well in some ways if it is half the price. It is certainly possible that the JBC has tighter or better regulation and that would be a benefit, but it is also certainly possible that the JBC allows you to set a lower temperature and it is thinking "average temp" instead of "maximum temp". If you look at their website, they sell this as a feature that puts them above their competition, that you can set the temp lower, but my question is if you truly compare the tip temps under use, how does that relate to the actual tip temperatures being executed. Since it is a sales point for them, I do have to wonder what the real deal is/temps are. A comparison where you have the ADS200 set 20 or 30 degrees higher may be inline with the JBC at a lower setting as far as actual tip temps, this is entirely possible. It is also possible that the JBC has better temperature regulation. What I wonder is which (temperature or regulation) is more responsible for the results of Dave's test... I suppose you could say both when you are testing at the edge.
I use my ADS200 under a microscope 90%+ of the time and the short tip distance is great.
The third thing is that Pace has more than impressed me on customer service. It is a big thing for me, but when a company goes out of their way to take care of their customer, I notice. I'll be honest, I'm not easy to please as my expectations for customer service are high. So many companies could care less about their customers or customer service so this is not a trivial thing. Their attitude with me has always been completely positive and how can they please their customer.
For me, the bottom line is in its price point, does it excel and do what you are looking for it to do. I came from a WES51 and I loved that iron. The ADS200 is a definite improvement in many ways, especially tip selection. I tried the FX-888 that everyone loves and was very disappointed with it. I know many love it, but I thought my WES51 was better in every way. I almost pulled the trigger on a FX-951 and was thinking about getting the microsoldering iron for it, but went with the ADS200 instead, so I can't comment about how the FX-951 would stack up against it, but I'm very satisfied with the ADS200. I would love to see a FX-951 vs ADS200 review someday, that would apples to apples price wise.
Several things that bother me concerning Dave's video evaluation:
- The Ridiculous 270°C/518°F Temperature: Does anyone here actually use 270°C/518°F when soldering?! Our irons are designed for use at 650-800°F. Why not evaluate at a reasonable/more realistic 371°C/700°F temperature setting used on most benches?! I'll assume that Dave always uses these low temperatures, which will always show JBC in a more positive light (see below about plating)
- JBC tips have much less iron plating than PACE tips: The iron plating on a tip determines affects the life of the tip: the more plating, the longer the life. However, it also affects performance because iron is terrible conductor of heat. It's a fine line: If you plate too little the tips erode quickly. If you plate too much they don't transfer heat well and take too long to heat-up/recover. We're always looking for that "Goldilocks" equation of "just-right." Related to the above mention low 270°C/518°F temperature, PACE will never perform as well at those low temperatures, since we optimize our plating for lead-free solder (highly corrosive to the iron plating) with about twice as much iron plating as the JBC.
- Why didn't Dave use the essential Tip Tool? Much easier to remove replace tips than the silicone grip.
TLDL;
It's not nearly as good thermally as the JBC CD-B, good 20+ degC difference in capability at low temp, I was very surprised. So much for "delivers unsurpassed thermal performance"
So no JBC killer, unless price is your sole driving factor.
Well built though and pretty sexy.
The display has some random number and overshoot weirdness.
Yeah, that PCB layout is kinda weird, but the overall construction quality looks amazing!!!
I'm not sure why the 15 sec setback delay is an issue — isn't that just making sure it doesn't go into setback when you're just setting it down for a second?
I would
love to see this station pitted against the Ersa i-Con series. The "full" i-Con models are 120W and use non-cartridge tips, but use a quite precision machined heater core and tips, and the heater goes deep into the tips. Distance-to-tip is also very small. (The "little" i-Con models, the nano and pico, are 80W peak. The nano actually uses the same heater as the big ones, just driven at lower voltage. The pico actually uses a different heater.) Even the little ones have a power bargraph, much like the JBC. They also have configurable power profiles — low avoids any overshoot, so heats gingerly. High heats aggressively and may have significant overshoot. Medium is… a happy middle ground. (I have the nano, and it's a lovely station, but its build quality, while very good, just can't compare to this Pace, which is actually priced about the same.)
Since we have Pace's attention, I'd also be curious as to why one doesn't design these things to use dual-voltage transformers. I would think that the simplified logistics of producing just one model, as well as the convenience to those of us who move overseas now and then, would outweigh the slight added cost…
JBC tips have much less iron plating than PACE tips: The iron plating on a tip determines affects the life of the tip: the more plating, the longer the life. However, it also affects performance because iron is terrible conductor of heat. It's a fine line: If you plate too little the tips erode quickly. If you plate too much they don't transfer heat well and take too long to heat-up/recover. We're always looking for that "Goldilocks" equation of "just-right." Related to the above mention low 270°C/518°F temperature, PACE will never perform as well at those low temperatures, since we optimize our plating for lead-free solder (highly corrosive to the iron plating) with about twice as much iron plating as the JBC.
How do the PACE tips compare in this regard to the Ersa tips? I'm just a hobbyist so I'm sure any tips would last forever for me, but everything I've heard is that Ersa's tips last freaking
forever. Is this also due to a thicker iron plating?
Several things that bother me concerning Dave's video evaluation:
- The Ridiculous 270°C/518°F Temperature: Does anyone here actually use 270°C/518°F when soldering?! Our irons are designed for use at 650-800°F. Why not evaluate at a reasonable/more realistic 371°C/700°F temperature setting used on most benches?! I'll assume that Dave always uses these low temperatures, which will always show JBC in a more positive light (see below about plating)
Dave has an obsession with fine tuning his tip temperatures rather than getting on with soldering.
My tips are around 400C, they're not adjustable, and I just get on with soldering quickly and properly. Leaded, lead-free, weird mixtures, high mass, low mass, individual pads on a 0.4mm QFN to TO-220 tabs, I never change temperature. Somehow, my joints all come out fine and things don't get damaged.
I think a Metcal in the lab might give him an aneurysm.
He's got a point about the imperial tip sizes, though. Do everyone a favour, dual label them on the tip and package as well.
JBC tips have much less iron plating than PACE tips: The iron plating on a tip determines affects the life of the tip: the more plating, the longer the life. However, it also affects performance because iron is terrible conductor of heat. It's a fine line: If you plate too little the tips erode quickly. If you plate too much they don't transfer heat well and take too long to heat-up/recover. We're always looking for that "Goldilocks" equation of "just-right." Related to the above mention low 270°C/518°F temperature, PACE will never perform as well at those low temperatures, since we optimize our plating for lead-free solder (highly corrosive to the iron plating) with about twice as much iron plating as the JBC.
How do the PACE tips compare in this regard to the Ersa tips? I'm just a hobbyist so I'm sure any tips would last forever for me, but everything I've heard is that Ersa's tips last freaking forever. Is this also due to a thicker iron plating?
To be honest, I'm not sure about Ersa, as we don't compete with them in the States too much. But our UK facility has probably done testing on them so I'll get back to you. I suspect they optimize for lead-free and are thus heavily plated, like PACE, and that's the reason they last so long.
Aaron
He's got a point about the imperial tip sizes, though. Do everyone a favour, dual label them on the tip and package as well.
That is a good point. I will bring it up to the production people!
Aaron
Since we have Pace's attention, I'd also be curious as to why one doesn't design these things to use dual-voltage transformers. I would think that the simplified logistics of producing just one model, as well as the convenience to those of us who move overseas now and then, would outweigh the slight added cost…
I've asked this question before, and there was a very good reason why we've never done this, even though we've been selling in 2 voltages since the 70's. But for the life of me, I cannot remember (I've got the CRS/Can't Remember Sh-t disease) the excellent reasoning against dual-voltage transformers ... cost maybe?. LOL, will have to get back to you ...
Since we have Pace's attention, I'd also be curious as to why one doesn't design these things to use dual-voltage transformers. I would think that the simplified logistics of producing just one model, as well as the convenience to those of us who move overseas now and then, would outweigh the slight added cost…
I've asked this question before, and there was a very good reason why we've never done this, even though we've been selling in 2 voltages since the 70's. But for the life of me, I cannot remember (I've got the CRS/Can't Remember Sh-t disease) the excellent reasoning against dual-voltage transformers ... cost maybe?. LOL, will have to get back to you ...
Concerns about people blowing them up by not being smart enough to look for a switch?
Dual primaries shouldn't be all that much more expensive.. and a switch is a couple bucks at most (in small quantity no less).
Isn't dual primary type just a matter of winding them with two conductors at the same time (so turn-count matches) and then soldering 4 lugs instead of 2?
Several things that bother me concerning Dave's video evaluation:
- The Ridiculous 270°C/518°F Temperature: Does anyone here actually use 270°C/518°F when soldering?! Our irons are designed for use at 650-800°F. Why not evaluate at a reasonable/more realistic 371°C/700°F temperature setting used on most benches?! I'll assume that Dave always uses these low temperatures, which will always show JBC in a more positive light (see below about plating)
High temps are good if you like to have on the tip a totally oxidized solder "paste" that can't flow, if you prefer a beautiful shiny melted alloy that can, around 300°C is the way to go.
- JBC tips have much less iron plating than PACE tips: The iron plating on a tip determines affects the life of the tip: the more plating, the longer the life. However, it also affects performance because iron is terrible conductor of heat. It's a fine line: If you plate too little the tips erode quickly. If you plate too much they don't transfer heat well and take too long to heat-up/recover. We're always looking for that "Goldilocks" equation of "just-right." Related to the above mention low 270°C/518°F temperature, PACE will never perform as well at those low temperatures, since we optimize our plating for lead-free solder (highly corrosive to the iron plating) with about twice as much iron plating as the JBC.
That must be why JBC tips last, literally, decades (when cleaned with moist sponges).
To be honest, I'm not sure about Ersa, as we don't compete with them in the States too much. But our UK facility has probably done testing on them so I'll get back to you. I suspect they optimize for lead-free and are thus heavily plated, like PACE, and that's the reason they last so long.
Yeah, Ersa seems nearly non-existent in USA, and wildly expensive when it does appear! (Whereas here in Europe, it's fairly common and affordable, and it's Hakko that's marked up like crazy.)
Speaking of facilities, what do you guys still do in Maryland? I vaguely recall that you've got a facility in Elkridge (which I used to live near), and used to be headquartered in Silver Spring (where I lived briefly)!
Since we have Pace's attention, I'd also be curious as to why one doesn't design these things to use dual-voltage transformers. I would think that the simplified logistics of producing just one model, as well as the convenience to those of us who move overseas now and then, would outweigh the slight added cost…
I've asked this question before, and there was a very good reason why we've never done this, even though we've been selling in 2 voltages since the 70's. But for the life of me, I cannot remember (I've got the CRS/Can't Remember Sh-t disease) the excellent reasoning against dual-voltage transformers ... cost maybe?. LOL, will have to get back to you ...
Cool!
I mean, for that matter, other than capacitors failing, why don't soldering stations use switch mode power supplies? Those eliminate the issue of having to set a voltage. (I have witnessed careless people forget to switch the input selector to 230V and then plug it in, so I definitely can see how that's a concern, as Monkeh pointed out!)
Speaking of facilities, what do you guys still do in Maryland? I vaguely recall that you've got a facility in Elkridge (which I used to live near), and used to be headquartered in Silver Spring (where I lived briefly)!
Yes, I'm located at the Elkridge Maryland site. It's our Engineering and Training Center. However, all ADS200's and tips are manufactured in our main North Carolina factory, not here. We only produce Fume Extraction and higher-end BGA rework equipment here.
Cool!
I mean, for that matter, other than capacitors failing, why don't soldering stations use switch mode power supplies? Those eliminate the issue of having to set a voltage. (I have witnessed careless people forget to switch the input selector to 230V and then plug it in, so I definitely can see how that's a concern, as Monkeh pointed out!)
I'll check it out! Thanks for the comments!
Aaron
For a company that's been in soldering this long I'm amazed they didn't realise that it's important to be able to rotate the tip.... what a fail!
Several things that bother me concerning Dave's video evaluation:
- The Ridiculous 270°C/518°F Temperature: Does anyone here actually use 270°C/518°F when soldering?! Our irons are designed for use at 650-800°F. Why not evaluate at a reasonable/more realistic 371°C/700°F temperature setting used on most benches?! I'll assume that Dave always uses these low temperatures, which will always show JBC in a more positive light (see below about plating)
My tips are around 400C, they're not adjustable, and I just get on with soldering quickly and properly. Leaded, lead-free, weird mixtures, high mass, low mass, individual pads on a 0.4mm QFN to TO-220 tabs, I never change temperature. Somehow, my joints all come out fine and things don't get damaged.
That's been my experience as well. Despite the advances in conductive soldering equipment technology, tried and true soldering/rework techniques are paramount.
With that mentioned, I do actually use the absolute lowest temperature I can, which means I have been very successful reworking with a 270°C/518°F temp setting. I do this when I can without an IR preheater or with an IR preheater when I feel pre-heating is warranted. The alloys I use allows me to do this with the equipment I have. As usual, there's a wide variety of situations where this setting is completely unrealistic, but I think the idea here is to use the lowest tip temperature possible for each job.
My personal opinion is Pace is an absolute outstanding company with almost everything they do and the ADS200 is another example of that excellence.
Lowest temp is not always ideal - higher temps can heat to melting point faster ( talking about thermal paths outside the iron) , so less exposure time. Trying to get the lowest temp possible will usually be counterproductive.
Several things that bother me concerning Dave's video evaluation:
- The Ridiculous 270°C/518°F Temperature: Does anyone here actually use 270°C/518°F when soldering?! Our irons are designed for use at 650-800°F. Why not evaluate at a reasonable/more realistic 371°C/700°F temperature setting used on most benches?! I'll assume that Dave always uses these low temperatures, which will always show JBC in a more positive light (see below about plating)
My tips are around 400C, they're not adjustable, and I just get on with soldering quickly and properly. Leaded, lead-free, weird mixtures, high mass, low mass, individual pads on a 0.4mm QFN to TO-220 tabs, I never change temperature. Somehow, my joints all come out fine and things don't get damaged.
That's been my experience as well. Despite the advances in conductive soldering equipment technology, tried and true soldering/rework techniques are paramount.
With that mentioned, I do actually use the absolute lowest temperature I can, which means I have been very successful reworking with a 270°C/518°F temp setting. I do this when I can without an IR preheater or with an IR preheater when I feel pre-heating is warranted. The alloys I use allows me to do this with the equipment I have. As usual, there's a wide variety of situations where this setting is completely unrealistic, but I think the idea here is to use the lowest tip temperature possible for each job.
My personal opinion is Pace is an absolute outstanding company with almost everything they do and the ADS200 is another example of that excellence.
Dave's stated premise was that you should solder at the lowest temperature possible. This is not exactly correct. You should solder at a temperature no higher than you can safely and consistently control the process. That being said, the inertia of bench techs, production operators and their supervisors is to turn the temperature up to maximize throughput and minimize the time it takes to reflow the solder (in either an assembly, rework or removal operation). Concerning the low temperatures used, even back in the eutectic Sn/Pb solder days, our guidance during our training classes was to start everyone out at 316°C or 600°F with solder that melted at 183°C (361°F). I believe Dave was using a Pb-free solder with a melting point of 227°C (441°F) at 270°C? I can’t think of anyone that solders at such a low temp using lead-free solder ... except maybe Dyaxxis? ;-)