At least your boiler had a manual, although it did not provide the answers you were seeking. I am daily infuriated by CAD programs that come without manuals. These are not cheap give aways like those free things I used to run across, but even thousands per seat does not come with a manual. They come with a web address for a fixed amount of time and then a, charge-by-th-hour service to answer questions I used to be able to find in the operator's manuals that came with AutoCad, or whatever program was the flavor of the day at wherever I was working.
Then add the fact that the help at the other end of the line can neither speak nor understand English.
That is far too often the case. There have been a number of threads recently about component substitutions causing failures. I also blame high turnaround. It seems that three years has become the normal tenure, instead of working until retirement. It seems that as soon as a product is out the door, that the product's designers, and all of their knowledge, are out the door too. The next thing you know Purchasing starts to complain about the sourcing on a component, and Senior Management pressures Engineering to accommodate the change without the time (read as cost) required to fully understand the change.
I worked for one organization that allowed Manufacturing Engineering to specify changes on a design without the approval of Product Development. Worse yet, Manufacturing Engineering didn't even have a EE on staff, so they just followed the recommendations of Purchasing. Purchasing even routed contested ECNs during lunch if one of the primary signatures was against their change. I know it sounds like the premise for a sitcom, but they actually made medical devices.
As an OLD Motorola alumnus, I'm exceptionally familar with the "M" seires parts. There's a legit reason for this: these parts have their own proprietary specs, and are SELECTIONS from the parent product line. The spec differences are (usually) narrow range of beta, and (often) leakage current, noise figure, etc. The "generic' replacement part (like NTE) will mostly work, but design margins may be violated and therefore performance degraded. In my 13 "batwing" years I probably set up several dozen of these P/Ns myself. So of course if you characterize a specific M9706, it will fit all the parameters of the MPSA64; however, the reverse is NOT true for other MPSA64s! Given your comment on "proprietary unit" I'm surprised that you didn't recognize that those "M" parts were too!
There is another side to this story that has not been brought up. I've worked in various industries for OEM suppliers and been on numerous system integration teams. For at least the past decade I've seen far too many OEM customers go with suppliers who had never worked on any component like that required for the system, and who subsequently screwed up the programs so severely that they had to be delayed (to the point of missing market windows in some cases!) or cancelled. The reason for the bad sourcing decision? Low bidder, without regard for qualifications! Perhaps DN needs a new blog series called "Managed by Morons."
I wonder how many times we have inadvertently installed fake parts into our systems. It is embarrassing to find a good design failing for no good reason. We suspect many things- circuit boards, wiring, etc. without thinking that little IC or transistor could actually have been defective to begin with. Unnerving, at least.
The error code was confusing. The blower appeared to be under some sort of control because when I unplugged the control lines it went to full speed (as it was supposed to). The service technicians wanted to replace both the controller at the blower to the tune of close to $1k. They lacked any diagnostics to isolate which was broken.
The bottom line: was it not working because the controller was defective, a sensor was defective, or the blower was defective? I do not like to replace parts without knowing with some certainty that it was actually defective.
Yes, I know, from a labor and overall cost perspective, given the lack of information on what the embedded system was supposed to do, their approach is cheaper.
I would have to agree with you Curmudgeon. The only way that such diagrams would be included is by regulation.
I also have to say that there were parts of this Munchkin manual that had to have been written with an attorney breathing down the neck of the technical writer. The first chapters of the installation manual were so littered with bold face large type warnings of dire consequences that it made reading the rest of the manual far more difficult than it had to be.
This is what I call the "Step Ladder Warning Disease." If you plaster too many cautions, warnings, and bold faced admonitions in a manual, few will read it and most of the public will continue to do the stupid things outlined in the warnings. Frankly, I have seen pilot operation handbooks (for aircraft), and even firearm manuals with fewer warnings than this monstrosity.
The solution is to undestand that this is indeed a gas boiler. Yes, natural gas can be explosive. There is also heat and condensate involved here. If an installer didn't know that, it is very unlikely a bold faced warning will teach them anything.
Attorneys need to understand that writing a manual that people will actually read and comprehend is an art form. The more they inject liability disclaimers in to the manual, the less likely it will be that anyone will be motivated to read the silly thing.
Some day I would like to see a conference between technical writers, engineers, and attorneys on how to build a better manual, because the state of the art right now isn't serving anyone well.
Truchard will be presented the award at the 2014 Golden Mousetrap Awards ceremony during the co-located events Pacific Design & Manufacturing, MD&M West, WestPack, PLASTEC West, Electronics West, ATX West, and AeroCon.
In a bid to boost the viability of lithium-based electric car batteries, a team at Lawrence Berkeley National Laboratory has developed a chemistry that could possibly double an EV’s driving range while cutting its battery cost in half.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.