It's called surge impedance, and it's the exact same thing that burned loads & nearly caused fires in another Sherlock Ohmsepisode: Noise Messed With the Automation System. Here is my explanation, copied & pasted verbatim:
It's called surge impedance Zo, which is defined as √(L/C), where L is the inductance in Henrys, and C is the capacitance, which for a coil is the interwinding stray capacitance.
The back EMF V= Zo (δI/δT), and it will have an oscillation frequency 1/(2π√LC). When you open up contacts in an inductive load, δI/δT goes to ∞: You see this as an arc when you unplug an iron; and also when relay & motor starter contacts are switching off an inductive load.
This is also why contactors have serious current deratings when switching off DC: Once the arc is established and current flows through the ionized channel, there is no zero crossing to extinguish the arc, as occurs with AC,
When dealing with AC, you design using the peak (not RMS) value of the load current when calculating, because you don't know where in the AC cycle the contacts will open.
Note: Those of you who are RF jocks will quickly recognize Z(o) = √(L/C) as the equation for the characteristic impedance of a transmission line: Yes, it's the same thing.
I am looking for a low 1-5v chatter method. Does anybody have any ideals. I would like to see the sch/design/specs of circuit. Because I am working on a new oxidizing graphene method similar to this fault. Maybe this is what my mom meant, when she always use to say to me, "I could be a preacher!. See what we can learn from chatter? Please contact me firstname.lastname@example.org wh circuit design info.
I am frequently confronted with supposed "Upgrades" that solve some sort of immediate problem, but lead to other problems somewhere else. To me this happens most often in assemblies. One of our customers is heavily involved in hood hinges and locking mechanisms in heavy over-the-road haulers. It is not at all unusual to begin to alter tooling to produce a part which will clear something that has been added under the hood only to be stopped before completion because the addition has been removed.
Years ago the company at which I worked sold the same die block to the same customer (3) times. We were producing a part and had to alter the die to produce a new version which did not work (for reasons I do not know), and we went back to the original design. This happened on two more occasions before product launch when they replaced the part altogether. So after paying for the tool and subsequent alterations they ended up with an expensive boat anchor and I had several healthy paychecks from overtime worked. It was a very enlightening experience in the operation of huge corporations where not everyone was on the same page.
One of the things this should remind us is that all LC circuits are resonant. I don't care if the resonance is way out of your operating range, something unintended will stimulate it. Always make sure they are adequately damped.
If, when they added that inductor, they had also added the right resistor in the right place, the upgrade would have never caused a problem. Of course, if they had done that task right, the dropout problem in the relay might never have been noticed.
When I arrived at Sunbeam/Aircap, the Chief Engineer proudly showed me the ceramic brusholder they had designed to keep the bakelite holder from seizing on the carbon brush of their motor. By examining some failed parts, I saw the spring collapsed and discolored, plus the solder gone from where the copper braid wire was connected to its metal plate - at the REAR of the brusholder. They brought 120 VAC to the brusholder by a wire attached to a small metal plate that was held against the brush braid wire plate by its spring. Vibration was bad enough to cause chatter between the plates, with heating enough to melt the solder. Once the solder left, the spring tried to carry the current, but its steel turns quickly annealed and relieved the pressure that held the brush against the armature, causing the ring of fire that made the bakelite swell and sieze the brush. About $50 k was spent on tooling alone for that "upgrade". Instead, we added a quick-connect tab intgral to the rear plate and connected power directly, eliminating a part from the BOM, saving money and warranty costs. Mike Harris
I understand that a reboot can fix the problem. But I don't know if that really solves the root cause of the problem. Somewhere there's something in the code that caused this problem. And if rebooting means the system will work right now, it doesn't necessarily mean the problem is solved.
Robots that walk have come a long way from simple barebones walking machines or pairs of legs without an upper body and head. Much of the research these days focuses on making more humanoid robots. But they are not all created equal.
The IEEE Computer Society has named the top 10 trends for 2014. You can expect the convergence of cloud computing and mobile devices, advances in health care data and devices, as well as privacy issues in social media to make the headlines. And 3D printing came out of nowhere to make a big splash.
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.