Does Current Flow on the Neutral?
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- Опубліковано 2 тра 2024
- There are a lot of people out there discussing this whole neutral thing and it can be a little difficult to understand what is going on without being able to see what is happening.
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Let’s start this off by stating yes, current does flow in a neutral. But there are times when it doesn't. To understand this we need to look at exactly where in the circuit we’re examining. If we are near a device, somewhere in a branch circuit, there will most likely be current flowing at that point. If we look further forward in the circuit, to the electrical panel, this is where things get interesting.
If a panel is perfectly balanced, and we have 2 loads that we are looking at, then each of those branch circuits will have neutral current flowing throughout the entire branch(es). But the neutral from the electrical panel back up to the transformer, will not. When two loads are turned on, and are exactly the same, the neutral current can actually balance out and, in fact, cancel each other out.
Neutral conductors from a panel back to a source will carry any imbalanced current that exists between any two phases on the system.
#current #neutral #electricity
01:10 - Panel Drawing
03:50 - Conductor drawing
05:00 - Magnetic field examples
05:36 - moving on
06:00 - Example of current on a neutral
07:00 - Better analogy
07:57 - Why does current disappear?
10:00 - Field interaction cancellation
12:00 - Circuit Diagram view
15:00 - Math (Ohms Law)
18:25 - Jules law
20:40 - Bringing it all home.
![[실시간] 전철에서 찍힌 기생생물 감염 장면 | 기생수: 더 그레이](http://i.ytimg.com/vi/4nkFvwxGAfA/mqdefault.jpg)
I am a senior technician, self-employed in the PCB manufacturing industry. Back when I was struggling with the difference between ground and neutral, I came up with an analogy using water that helped me better understand. Imagine you had an upstairs laundry room. Of course, there would be a drain in the middle of the floor just in case the washing machine sprung a leak. But, in normal use, the water in the washing machine would go down the intended path through the drain behind the machine. The drain in the floor acts the same as a ground. It's not an active part of the washing machine plumbing but if necessary it can carry the water away to avoid flooding the downstairs. The drain behind the machine acts as the neutral because it is intended to carry the water away in normal operation.
Makes a lot more sense than this overcomplicated video..
@@MF-kr4hfif you ever want an over complicated answer, ask an electrician
@galenmarek8287, apparently you've had a conversation with the master electrician I've worked for....😂
What an awesome analogy 👏
I was under the impression that the white wires were the safe ones. I was 19 years old up on a twelve foot ladder working in a commercial building. I was working the fluorescent lights hot because it was a problem shutting them off. So 10 feet off the ground I learned that the white wires are extremely dangerous. Fortunately I didn't fall or get injured. After that horrible shock from 277 volts, I was really having second thoughts about the trade I was getting started in. I'm a retired 68 year old electrician and by the grace of God, still able to talk about it.
@McNea goodmorning...ahh do you like hamhocks or neckbones with your collard greens 🤔
Older guys (my gdads age) used the saying “only touch one wire at a time and you’ll be ok” which is absolutely untrue.
A break in the circuit path neutral or hot is a place to get hurt.
dude, a grounded conductor only has zero volts until it is disconnected from the neutral bus. onces it is disconected the voltage increases to that of the ungrounded conductor, in your case 277 volts, when you touch that and then touch ground you become a big assed human resistor to ground. current flows......that hertz real bad.
A grounded conductor would mean it's grounded wire, correct? Implying it has a charge, but still it's a ground wire.
just a joke: This is why you pay attention in physics class.
I wish all electrical tradesman were as cool and down to earth as this guy and willing to teach... I would've learned so, much faster and much sooner in my career.
Many are, it’s just that the loudmouth types are usually the lead man.
Facts
Still can and still are brotha! Never stop learning!, but i get your point for sure, didnt start in the filed until i was 28 to 29 yrs old.
Learned more about electrical in two vids than talking to more than 200 electricians. Thanks for the solid work man.
For what's it worth, I actuallty liked that you didn't have the "schematic" drawn already. Not sure why, I have seen you draws these dozens of times, I guess it just gives me time to process it things and get my mind in the right frame for what you're about to discuss.
100%
This part
@@tylerrcasement what is Dustin Teaching 🙏🙏🙏
Agreed. I'm not an electrician but as a homeowner that fixes/improves things it helps me to see how it all goes together.
@@kevingray8616 Hi
As an electrical engineer, that was an excellent practical description of current flow in an AC circuit for an electrician. Yes, there is a lot more complex math, but the bottom line, your description and drawings were spot on. Kudos on your presentation skills.
Agreed. I'm an IT network engineer who started his career in electrical engineering. A great background or secondary degree for IT, BTW. :)
A lot more math and physics 🤣🔥
@@mathman0101 especially if doing 3 phase
Amen Jim. From 1 EE to another. Great delivery.
This is the most arrogant and condescending comment I've read in a while
We had fires in our office cubicle walls back in the 1990s due to excess neutral wire current.
The cubicle outlets were spread among three 120V phases with a shared neutral wire. We all got office computers that had non-linear power supplies: their AC inputs were bridge rectifiers feeding big capacitors. AC input current only flows in spikes on the peaks of the AC voltage to charge the capacitors.
In a 3 phase configuration with balanced resistive loads, there is zero neutral current; the current flows (push and pull) cancel. In our configuration, the current spikes on the AC voltage peaks occurred 120 degrees apart, so there was no cancellation. The neutral wires were overloaded and caught fire.
Facilities opened up the circuit breaker panels and used an infrared scope to look at the neutral wires to find the ones that were hot. They then ran new dedicated circuits to feed the computers on those wires.
Nonlinear devices (power supplies, VFDs, and others) contribute harmonic distortion onto a power distribution system. Certain orders of harmonics called triplens (includes the 3rd, 9th, and others) do not cancel out even in a balanced three-phase system. Triplens specifically sum on the neutral. A three-phase system with a large percentage of nonlinear loads (depending upon the type of course) may see triplens. Where applicable, this means more heating on the neutral which is even worse the more unbalanced a three-phase system becomes due to connected single-phase loads. Assuming no other means of mitigation is employed, a smart engineer will oversize a neutral for this reason (perhaps 150% or even 200% compared to the phase conductors). This is also a reason to specify a distribution transformer with a K-factor rating that is selected considering the total percentage of nonlinear loads.
Just found your channel and I'm very excited about it. Thank you so much for taking the time to explain these things!!!
Get in between a neutral splice and you'll find out REAL QUICK...!!! 😳💥⚡
yea im not doin that again
Back in my first year of apprenticing I was working with a journeyman who sent me to find an open neutral in a junction under the house and when I found it and asked him to turn it off he said what do I gotta turn it off for you’re just fixing the neutral connection…trusting him I started pulling on the connections and got a nice zinger.
It will bite you
Espically on 347 volts ,line to neutral , you don't want to get between the hot and neutral . canadian is 600 volt line to line .
Voltage is not the same as current. If you have an open neutral it is no longer a 0 volts wire. It's now energized to 120 because there's no path back. At which point it's technically not a neutral. Anytime you touch a wire under load that has current running through it, if there's less resistance through your body to ground than there is in the wire you will get a shock.
This is probably one of my favorite videos you've done. Good job! I liked how you got into the more scientific way of explaining your point, but keeping it simple enough for the beginners and apprentices. Keep up the good work. Thumbs up!
Hi Dustin, just came across your channel this morning and it’s GREAT. I watched “does current flow on the neutral “ and I’m hooked. I’m an old carpenter /contractor with a 20 year old grandson in his 6 th month of apprenticeship as an electrician working for a midsized contractor and he loves it. I texted your channel info to him. Thanks again. Dave The Carpenter in Omaha .....43 years in business.
I swear you are a lot better explaining material than college professors … keep going brother … wish to see more valuable videos
I knew the answer, but watched anyway because I like your teaching style and enjoy watching. A topic you may want to consider is (for the general public) how to select the proper size generator or inverter to meet grid down needs. I find myself giving the same advice in comments over and over, and would rather just refer them to a good vid.
I also knew the answer and i'm from Australia so i figured i'd watch to see if he gave the correct answer as so many sparkies in Australia fail to understand these fundamentals
I agree, overall he did a good job
Great idea! That would be an awesome video! Also a classroom style theory lesson like this on OHMS would be awesome!
Electrician U is easily the best source of info for Electricians on UA-cam. I always recommend this channel to the Apprentices on my job sites.
I would agree with you for apprentices and people new to the trade for people with experience most of his topics are as basic as they get like 1st year stuff
@@juliovalencia4948 Which is the point. I've been in the trade for over 35 years and I still like listening to him.
Thanks so much, that means a lot!
@@ElectricianU I learn lots here also. Was taught wiring at 10 years old, by a engineer- neighbor. You add to that every video.
To each their own
I think the best way to explain it, is to actually draw the sine waves showing the cancellation of voltages with balanced loads. That way, the neutral (transformer centre tap) looks more like the voltage balancing wire that it actually is since both upper and lower sine waves naturally oppose one another relative to the centre tap. Make it all in phase for the drawing so that a second set of amperage sine waves is positioned below the voltage sine waves with equal and varied amplitudes for equal and unequal loads. And any time it is unequal, show what proportion of current is flowing in the neutral compared to the rest of the circuit.
damn that is the best way I ever heard explained
are you saying that the two phase in his example are 180 degrees out of phase with each other? I thought the phases are 120 degrees out of phase which would show a net lower amplitude wave.
He's still describing a single phase system, not 2 phase. Do a google search on two phase to see the difference. @@johnreuteman2724
@@johnreuteman2724 I don’t like how the two different hot lines are described as “phases”. The hot lines or legs are from ONE 240V phase, but that phase is split into two equal halves (120V) by the neutral wire (which is grounded at the pole) in the center of the phase coil. Now he’s correct that these 120V halves are opposite in polarity (by 180 degrees)-again if the neutral is referenced / grounded in the middle of the transformer coil-and these two legs essentially cancel each other if their loads are equal. The 120 degrees you’re thinking of is the difference of the 3 phase power lines that come from the power company/substation. Power is generated in 3 phases with the waveforms being 120 degrees apart. Commercial and industrial properties are often supplied with 3 phases of power (ie. to run 3 phase motors & equipment), but typically the US residential homes are supplied with only 1 phase of power and that 1 phase is split in two by tapping the center of the secondary coil of the distribution transformer on the pole. The transformer for a residence in this case is supplied with only ONE phase from the substation (typically 7200V ph-N) and so the secondary side (typ 240V) is also only ONE phase. The confusion between 120 deg “out-of-phase” 3-phase power and 180 deg “out-of-phase” 1-phase power is exactly why I don’t like to describe the 120V legs as “phases”. Hope this helps.
@@ALM1936 On a single phase system, isn't it true that the neutral will bite you harder if there is a full load on one hot wire and no load at all on the other hot wire?
Thank you for this explanation it's been a question that I've wrestled with for the same reasons you said it aggravated you as a helper. This style of information presentation is excellent for those who did not have formal education in AC theory, or has taken AC theory but decades ago and cannot remember.
This is absolutely incredible, I remember watching this 3-4 years ago just out of curiosity for the trade. Seeing this channel grow and continue to educate is amazing, I really appreciate the time and effort put into this. I’m a chef, not even an electrician and I watch most of these videos.. so thank you!
As an electrician who fell in love with cooking later on in my life. Thank you!
I was a chef for 20yrs, then covid happened, went on furlough, did a little off the books landscaping to supplement UI.. Now I’ve been an apprentice electrician for a year and already make about an the same as the most I ever made cooking. And I have a lot of weekends off now😁
At a small-ish company doing commercial and industrial only, I can definitely say on average this trade is far less physically and mentally draining than cooking. And the money is sooooo much better.
There’s a shortage of electrical workers nationwide. Just putting that out there. Sometimes I miss the kitchen but overall I’d say switching to this trade is the best career decision I’ve ever made
Lol...
Good for you, sport.
@@bradleywillis1654 yes. It's a simple trade and they are spoilt and over paid. So enjoy the money while it lasts, sport. Things are changing....
There’s a higher demand for us then ever but yet we’ll make less money in the future. Only in ur world, sport.
As a practical point to novices doing wiring. Of course whenever possible turn the power off before connecting wires. But remember if you touch between two neutrals you can become a load. In effect you put your body in series with that circuit path. So the assumption that some people have that "the white wires are safe" is bs.
Been there done that. Learned fast
Don that is so true! When I was a lineman guys would get careless handling neutrals, especially during storm trouble. Get yourself between an open neutral or a tool between an open neutral and you can find out the hard way.
Also why code doesn't let you put two neutral wires under one stud at the panel.
I don't know the NEC codes of today, but I recall an old tale of a plumber being electrocuted working on a water meter because the main neutral was bonded to the house side of the water pipe and not the street side. True story? I have no clue.
@@smitlag that’s not a code thing. That is a requirement from the manufacturer of the panel.
It would be nice to see real wiring, real light bulbs and real meters showing the amps and voltages. Nice informative channel.
Light bulbs ? All a light is -is resistance between to connections. It not matter voltage , lights still work on all volts. You can not test voltage by lights. Must be by a volt metter for volts or a amp probe for amps and a hertz counter for hertz. Hertz is very important , it the speed of the volts and watts on material by the second. Usa is 60 hertz per second as south east asia and asia and middle east is 50 hertz per second. It ok to run a transformer for 50 hertz per second in a 50 hertz per second area . But not run a 60 hertz tranformer in a 50 hertz area. The 50 hertz core is thicker than a 60 hertz core so the curent can move slower on the thicker core , but can not move to slow on the core that the core made for the size of hertz travels over it. The slower the travel equals the thicker the core must be so it not melt.
I get what you mean. As you would see it on the field. Maybe photos would help a bit. IMO, anyway.
Thank you ! This was amazing. I'm being trained to become an apprentice and this was very enlightening. I'll share my notes with my classmates and direct those who speak english to this video.
Dustin is so good that one of my teachers in my trade school just used his videos to fill up the entire class period on Zoom. Maybe because he was lazy, who knows but the fact that these videos are so educational and informative that they can be used as real in-class school material is amazing and shows its quality and value haha.
For me, the way he talks is like he is talking to a friend rather than a superior.
He is able to maintain the attention of the younger generation and keep things interesting.
Dustin should be teaching trade school. His teaching skills are amazing.
Sounds like most trade schools. They suck. Most are filled with instructors who are looking for a little extra cash and don’t really care about the student. People like this guy and myself actually care about educating the trade one student at a time.
Sounds like a lazy teacher, you pay to be taught, the video should be homework, & review, & expand on in class! The video should be used as a supplement and watched on your own time, very lazy teacher! But yes his lessons are very good
Also, omissions are dangerous. This is dangerous.
I been watching your vids since I was an apprentice and they helped me a lot to get my Journeyman’s card. Now I’m on my way to get my masters and I’m sure I’ll pass it.
That's great to hear - good for you!
Have been loving your channel lately. Had an addition done on the house and while I feel comfortable changing an outlet or a switch, really didn't have the knowledge that you and my new, very talented and willing to teach, electrician have provided me! Added a 240V outlet in my garage and a 30a 240v generator inlet with an interlock in the panel. I watched and learned, and, while I'm not willing to touch a switch without turning off the breaker like I see so many pros do, feel much more confident in my abilities!
As an electrician for over 20 years, NO pro will ever work on any live circuit unless absolutely necessary, and even then only with the proper protective gear. Arc flash is no joke. Our first impulse in an emergency is to inhale a big gulp of air in order to be ready for what is coming our way. Arc flash produces metal so hot that it is a gas, and when that is inhaled into our lungs, the internal damage it causes is no joke.
I have seen holes in electricians hands from when they did not properly turn off power and lock out a lighting circuit. When someone works on live circuits, it shows that they are a non-professional, and are gambling with their lives. The only time I ever had to work on a live circuit was due to damage in a server room, so secondary and backup power was lost, and I was standing on an insulated pad, wore calorie clothing with a insulated coat, wore full goggles and a face shield, a dust mask, and insulated gloves, and used insulated tools.
If an insurance company or workers comp insurance finds out that an insured employee was injured while working on live circuits, they will usually sue the company or even possibly refuse to cover the injury costs if the employee knowingly violated company policy. Most workers do not realize that if they violate the company rules and printed safety warnings on equipment, they can be SOL when it comes to insurance or workers comp. The warnings to not stand on the top two steps of a ladder is a prime example.
Insurance companies want our money, and giving it back in claims is the last thing on their list, and companies will go along with denying a claim because they don't want their rates to go up.
I believe it was Einstein that said that you can’t be sure that that you know something until you can explain it to a 6 year old. I am pretty sure Dustin can explain these fairly complex concepts to a 3 year old . Half of the enjoyment I get from watching this channel is watching Dustin put his excellent communication skills on display. Dustin you have a great gift to be thankful for . Thanks for sharing it with us!
glad you you understood it, maybe you can explain it to a six year old and get him to explain it back to you in six months time just to be sure he understood it and retained it.
I don’t understand this 😭
@@cameron6803 it would help if he would get rid of all of the extra parts while explaining neutral, and actually explain why there is a wire in the middle of the coil.
Really? I think it's horrible!
One of the best explanations I've seen on this subject. Imposed just enough theory on electromagnetic fields to demystify the operation for the lay person, while addressing the various scenarios.
Thank You for another great video. It is difficult explaining a lot of electrical theory. It's really a pain in the butt explaining it to an electrician who kind of has their own theory. This one in particular seems to have been taught to a lot of Sparkys that I have worked around in a rather rigid way. So many of them will swear that two loads that are, say 5 amps each, will perfectly balance out and no neutral current will flow. Every one of them that I challenged to remove the two connections to the neutral bus and tie together then use any two fingers to complete the circuit back to the neutral bus, hot, just plain refused. Finding out how much they knew about WHY was revealed when I just asked them to explain the whole thing to me. Most of the time I was just told to take a hike, journeymen, dunno why most of them are so . . . stiff. Every time that I 'had my bluff called', I explained it with Ohms Law and showed the phase differences. I also would ask them why the neutral was there if it wasn't used.. I ALWAYS said that there is theory and there is practical use. They are rarely EXACTLY the same. Kinda like explaining how to drive to someone on paper, the finesse that is required in practical use is a bitch to explain on paper. Background: Retired after 30yrs as electronics tech in a facilities management department. I worked with two master electricians, one was educated in Germany and came to the US, the other has master tickets in five states. These two were very interested in learning more about electronics and I wanted to know more about power & distribution. We were a pretty cocky crowd and we loved a good problem. Open minds, required in service work.
That is eye-opening. Thank you for this. Now I have to let it soak in and mull it over. Lots of new info and different ways to think about things I thought I already knew…. You are a great teacher.
Great Video!
I'd like to see your take on how much power travels through the ground (and you can use your green marker more appropriately).
If I may add my 2 cents to this tutorial:
1) In a Branch circuit, where you have a Black, White, and Green, technically the White is not called a Neutral. The correct term is the Grounded Conductor, and there is current on it, because the current has only one path to get back to the Source.
2) In a Single Phase system, as you would find in a Residence, where you have (L1), (L2) and (N), the Neutral is there to carry any unbalanced load between (L1) and (L2). In a perfect world where the distribution panel was perfectly balanced, there would be no need for the neutral. However, since you have both 120V and 240V appliances in the home, then the Neutral is needed.
To simplify the " PUSH-PULL" that Dustin talked about, it is important to remember that in a Single Phase system, (L1) and (L2) are 180 degrees out of phase with each other, meaning that when (L1) is at +180 degrees, (L2) is at -180 degrees, so when their currents meet up on the neutral, they basically cancel each other out, if their numbers are the same (+2A) and (-2A). (See Kirchhoff's Current Law)
Σ IIN = Σ IOUT. Kirchhof's First Law, conservation of charge.
There. Now we have a gen-U-whine formula (if simple) and I'm sure there will be some EEs tying themselves into little knots pretending it doesn't apply.
@@ethelryan257 Kirchoff is your friend! 🙂
Better bone up on AC circuits vs DC circuits because in an AC circuit you are dealing with Impedance, not resistance.
As soon as your load has anything other than pure resistance (incandescent lamps) there's phase shift between voltage and current and Power Factor comes into play. Think multiple devices that present reactive loads from motors, fans, ballasts and power supplies.
Sure, laws of charge conservation still apply, but are your ready to do the math?
With a low Impedance EARTH connection bonded to the Neutral buss in the panel how does that affect what he says? Does what he say about overloading the neutral connection (center tap) from the utility being of concern make sense? It didn't make any sense to me. What about branch or sub-panels?
Remember, this is AC power in a 3 wire 2 branch single phase L1-N-L2 120/240V configuration.
@@hbmike47 1) " Better bone up on AC circuits vs DC circuits because in an AC circuit you are dealing with Impedance, not resistance. " . . . . . . . . . . . There is Resistance in AC circuits as well. Impedance = Resistance + Inductive Reactance + Capacitive Reactance
2) " As soon as your load has anything other than pure resistance (incandescent lamps) there's phase shift between voltage and current and Power Factor comes into play. Think multiple devices that present reactive loads from motors, fans, ballasts and power supplies. " . . . . . . . . . . . A circuit with mostly Inductive Loads will cause the Current to Lag the Voltage by 90 degrees. A circuit with mostly Capacitive Loads will cause Current to Lead the Voltage by 90 degrees. A situation like this will cause the Power Factor to be less than 100%. However, these conditions are found mostly in Commercial and Industrial Power Systems, not in Residential. That being said, Phase Shift and Power Factor does not change the PUSH PULL narrative that Dustin spoke about, and the fact that current does flow on the Neutral in certain conditions. The point remains that Single Phase systems are separated by 180 degrees, and 3 Phase Systems are separated by 120 degrees.
3) " With a low Impedance EARTH connection bonded to the Neutral buss in the panel how does that affect what he says? " . . . . . . . . . . Connecting the Neutral Bus to EARTH puts it at the same Potential as the Ground/Earth, which is zero. There is no voltage on the Neutral, but there is current. If you put a Voltmeter across Neutral and Ground wires in a circuit, the meter will read zero.
@@hbmike47 " Does what he say about overloading the neutral connection (center tap) from the utility being of concern make sense? It didn't make any sense to me. ". . . . . . . . . If you are referring to the portion of the video at about 13:41, he is describing a situation where you have 2 circuits from the same Phase, (L1), essentially sharing a neutral. Because the circuit "Hots" are from the same phase (L1), there is no cancelling of any unbalanced currents, instead they add. So if one circuit had 3A on it, and the other had 5A on it, you would have a total of 8A on the Neutral going back to the source.
Really an excellent explanation! Important to understand for multi-wire branch circuits as an explanation of why the hots need to be on different phases.
Your explanation of this complex concept really helped to clarify my confusion. I will continue to support your channel because I know you will help me to learn how to be a great electrician.
Wow. This is a great video. Super cool how you described how the two hots are out of phase with each other and would cancel out in a balanced circuit.
You should do a video on 240v circuits that don’t use a neutral. For instance a well pump. How it doesn’t need a neutral because it’s 240v only. That’s something that took me a minute to wrap my head around as I was learning.
And then there's devices that use 2 phases, a neutral, and a ground, like electric dryers! The heating element is powered by the 240v, but because the socket provides neutral, things like light bulbs that illuminate inside when the door is open can be normal 120v bulbs because it just grabs power from one phase and neutral.
@@Lierofox In the US, that's not two phases.
@@ethelryan257 Yep, misspoke, 2 lines, not two phases.
@@Lierofox it’s kind of silly that a lot of dryers also require a neutral. If some of the controls and control illumination/screens require 120v, they could engineer the dryer with a control power transformer inside to get 120v control power off the supplied 240v circuit.
@@RB-xv4si Doing so would add complexity and cost to the dryer.
Also, if you use voltage divider rule, each lightbulb has a voltage drop of 120v, that is another way to prove the concept
Hmm, without additional info that does not prove anything. As in the case of an incorrectly wired MWBC you would see 120 drop across each bulb with double the current flowing on neutral.
Yes, the lamps are simply 2 resistors in series with 240v across both. Each lamp drops 120v.
Great explanation. I enjoy your videos. I'm not an electrician but have a math/physics degree and do live sound and have worked in a lot of aspects of IT/networking. You help me bridge the gap between my theoretic knowledge and the low voltage practical knowledge that I have to make me more confident in approaching things around the house. Even if I don't tackle them myself, I'm able to speak more effectively to electricians I hire and to scope out work for them. Thanks.
This was extremely helpful because I really was wondering how current flowed from the transformer to a load and back. Thank you!
Thank you for all these great presentations - as a mechanical engineer (from FoMoCo) decades ago, I am learning a lot from your productions (or forgetting a lot from my age). I agree with fellow viewers that it is better when you draw your presentation as you give explanations as it allows the "students" to follow your mind process instead of being "flooded" with a complex diagram to start with. BTW, what kind of interactive whiteboard screen are you using? Thank you again, Ciao, L
This would be a helluva lot simpler if you just show the two wave forms on a graph. The user could see that the troughs intersect at zero, and the peaks are the same magnitude and different polarity. This graphically shows the math, which equals zero along the whole line.
I was kinda thinking the same thing. I'm only halfway through the vid, so maybe he addresses it better but it seems like showing the pushing/pulling that the two balanced loads are doing, resulting in no net change in electrons in the neutral bar, would better explain why there's no current on the neutral.
Ya know, that's the way I usually draw it out to explain it, but that doesn't click for everyone, I am going to try explaining it more like this
If the neutral is balanced (cancelling out), does the current flow across the other hot wire? That's what I thought he was showing but I'm not sure about the bulbs becoming a part of a 240v circuit etc ...
I love that you so people things in multiple different ways, to make sure they get it.
OMG!! I have wondered for years why the neutral bar in a panel wasn’t hot!!!!!
I always understood why the neutral may be hot at a switch/outlet.
THANK YOU!!!
I always understood why the neutral may be hot at a switch/outlet... oh yes?
There obviously ought to be a neutral present in a socket outlet or an appliance isolator, or a spur outlet... but in a light switch (at least in the UK) there ought not to be a neutral... The neutral wire, at one time black, now blue, is used as a switched live, flagged / identified with a piece of red insulating tape... Most of the time...
I wish my college professors were this good at explaining electrical theory when I was in engineering school. Your videos would have been a game changer for me back in the day! Nice job.
Ive been a lineman for over 10 years and I have to say I like where your going with this presentation. Its hard to grasp all the intricacies involved with electrical theory and after all it is just a theory. The best way I have found to explain the neutral in regards to a 120/240 service is it neutralizes the unbalance between both hot legs. If the panel in the building always had equal load on both legs the neutral would not be needed. When I troubleshoot an open neutral to determine if its on our side or in the home. The easiest way is to clamp an amp meter around the whole service. If the neutral is good it will read under 1 amp regardless of the load. Because current going opposite ways cancel out in the meter.
After all it is just a theory? You might have the wrong definition of theory in your head.
This isn’t correct at all
@Ryker u can only clamp one wire at a time, measuring amps not volts.
Of course you need a neutral wire, it connects to the light bulb
benjamin thomas especially at 8.40
to be honest I like that you're drawing as you go, it helps to understand how everything is connected
Great video... it got confusing (and I already knew this!) with all the twists and turns you were taking, but you finally got there and I remembered that my understanding is not the same as others and it sometimes takes a different route to explain things to arrive at the same point... LOL Great way to "round-up" all the stragglers getting lost in the weeds so they can understand everything as well!
This was great, and I thought was going to address a confusion I have...almost did, but then didn't. I think someone else commented on this, regarding lots of time spent on the balanced load, but not enough on the imbalanced load. I get the 8A back through neutral, but I can't figure out how this is tied to ground at the same time. Arg, electricity is freaking magic as far as I can tell. Keep up the great work. I love this channel.
At the service entrance to your house (at the main panel) the ground and neutral are bonded together. This is the one and only place this bond occurs per the National Electric Code. This is done so that if a current carrying conductor (phase or neutral) touches ground, the stray current has a low impedance path back to the source which will allow a circuit breaker to quickly interrupt the fault. In a perfect world, current never flows on a ground. Think of the ground grid as a safety/backup path which stray current can escape on back to the source (instead of through a person for example). Neutral conductors are designed to carry current, unlike a ground. Think of a neutral as the normal/intended return path for current to flow back to the source.
A neutral(grounded) conductor is VERY important for balancing your house voltages.
READ ON to find out why.
When I was younger, I would often see the lights in the house get much brighter or get dimmer, even blow bulbs.
I measured the voltage on the outlet and read 190 Vrms!!! (Line to neutral at receptacle)
Never knew why till I took a class on electricity and the showed what the neutral is used for.
Take a look at the upper diagram at 12:35.
If you remove the service neutral wire and you have two different sized loads on L1 and L2, it forces the load voltage on L1 and L2 to shift till the current is the same through L1 and L2. Essentially, the two loads on L1 and L2 become a series circuit because the connection to neutral is lost and the 240 V across L1 and L2 are divided across each load on L1 and L2.
Let's use numbers to make it easier to see.
A light on L1 of 100 W and a light of 60 W on L2.
Using power formula, P = V * V / R. Therefore R = V *V / P
100 W bulb has a resistance of 120 * 120 / 100 = 144 ohm.
60 W bulb has resistance of 120 * 120 / 60 = 240 ohm.
If the neutral is "open" the total 240 V is across both light bulbs in series and the bulbs form a series voltage divider.
Total current is total voltage / total resistance.
240 V / ( 144 + 240 ) = 0.625 A
To calculate voltage drop on each bulb, take current * bulb resistance.
100 W bulb has voltage drop of 0.625 * 144 = 90 V
60 W bulb has voltage drop of 0.625 * 240 = 150 V
YES, that's right! The 60 W bulb is now at a 150 V and will not last long.
After taking the electrical class, I realized what was going on.
The service neutral wire was loose causing the current to balance to the same value by shifting the voltages on L1 and L2 at the main service panel.
When I put my hand on the electrical service panel, IT WAS HOT!
The "poor" neutral connection was generating loads of heat and system voltage shifts!
190 V on a 120 V receptacle(line to neutral) is one hell of a shift.
That is why our TV circuit breaker(built into the TV) and our bulbs kept blowing and tripping.
Incandescent bulbs literally breaking.
Tightened the service neutral connection and problem solved.
(No aluminum connection problem CU wire only).
Don't even get me started on AL wire on CU only outlets! That's scary sh!t.
It would have been good to address this in the video. Bad neutral connections have destroyed lots of equipment and the lights dimming and brightening are a big clue.
Yeah, unfortunately most people like me don't know that lights getting brighter or dimmer is a problem within their own home. I always thought it was just a power fluctuation everywhere.
Great explanation to the topic. Makes me absolutely stop adding circuits to my house until I see how it applies to determining where and how to add a circuit.
I reallly love the way you explained everything in this video.. i remember when i was learning i could never understand this because my teachers had a difficult time explaining it in a way everyone understood. I am so bad at explaining how Electricity works to someone that is new and teying to learn cause i makes sense in my head just cant put it in words. You have a true talent at explaining Electricity
I remember working for a college radio station about 50 years ago. We always made very sure that the loads were balanced on both sides of the neutral, both to make sure that the neutral was not overloaded and to keep any transient noise in the audio equipment (vacuum tube days) down.
Oh my! Taking me back to the beginning. Critical circuits would have trimming resistors. Amp tubes in the final would have inductive trimmers. Fortunately some tech from years gone by would have made notes in station maintenance logs so those could be preset with no power/low power.
@@thedillpickle100 that is very interesting.
@@thedillpickle100 - And you always installed a bleeding resistor on the pot capacitors. Once they overtightened the resistor leads and ended up with an open, which they then didn't test. So, when checking to be sure that the capacitor was fully discharged, we ended up with an arc-welded screwdriver (after a rather spectacular flash!).
Nicely done. Would be of interest if you mentioned the consequences of an unbalanced load with a poor neutral connection and maybe some mention of the sine waves on the two phases that causes the push / pull effect on the neutral.
This video was incredibly informative and easy to follow. I just stumbled into your channel, and I'm here to stay.
I love this video, I have always had issues with A/C wiring. I work on equipment so I know DC like the back of my hand. I do change my own breakers, lights, and switches but I have always left the inside of the breaker box(breakers slot in so I don't consider that inside really) to electricians. Thanks for the video.
Fun Fact, the balance and cancellation phenomenon is used in Pro Audio to neutralize electromagnetic interference on XLR audio cables. They're "Balanced" so that what you hear after amplification is actually the imbalance. If you plug a stereo audio feed into an amp through a balanced connection, you instantly get a karaoke track, since the instruments are rarely centered on the feed, but the main vocals are - the voices just "disappear". If you've ever had issue with the audio feed on a UA-cam video and others report it is fine, you are hearing the digital version of this.
Though you’re on the right track, that’s not entirely true. This would only occur if identical doubles of the vocal track were 180° out of phase, panned hard left and right and summed to mono. But the principal that, similarly to electricity, speakers are incapable of pushing and pulling at the same time.
No, if L and R are identical, i.e. voice in the middle, L minus R will completely cancel the vocal and anything else that's fully centered. Discovered this when I was 10 when I connected each speaker's minus wires of our stereo system together but not to the speaker ground. It was so cool to hear the instrumental version of my favorite records. Now they put a lot of stereo reverb making full voice removal harder to achieve unless you use AI techniques.
Finally. FINALLY someone explained wtf is going on with the neutral to a level of detail which ACTUALLY answered my questions. Like you said at the end of the video, the current has to go SOMEWHERE, it doesn’t just disappear on the neutral! It gets cancelled out by the other hot. Thanks Dustin!
I guess I misunderstood? I thought it got canceled out on the neutral line (bar) and was forced to reroute to the source by the closest black hot?
Ended up been lost in the colour at the end but loved it, I ended up understanding lightening. Brilliant.
This guy is a great teacher and he explains it very clearly. Ive learned alot from him !
It would have been a little easier perhaps if the phase plots of the voltage sources were shown too. This would also help explain in 3 phase Y, that the neutral carries the delta current, and how by phase, each leg will return a portion of the others current.
I don't know electrician lingo but it would not be the delta it wit would be the sum. Hot + center tap = 0
I LOOOOVE this explanation. It neatly lays out the concept of how current travels on single split-phase systems and cleanly explains WHY the neutral feeder will usually show very little current flowing while neutral current shows in the neutral wire going from the load to the neutral bar. It also explains why shared neutrals in both single-split-phase system need to be carefully thought out so as not to overload the neutral wire to the point of burning it up. I don't believe shared neutrals in a residential setting are common to begin with.
A continuation on this subject in a follow up video that explores three-phase commercial systems would be fantastic as shared neutrals seem to be incredibly common in commercial settings.
Question, (I'm fairly new to electrical) the diagram at 16:43, is this possible to wire? The hot from one phase connected to the hot of another phase with say a light bulb in-between. Will this work or be a fireworks show?
@@brandondill4234
What he had set up there was two 120 volt bulbs wired in series. Yes, they would work fine that way.
@@brandondill4234 Theoretically, you could. But why would you want to do that? Lamps are designed to run at 120 V and if you were to wire two 120 V lamps in series, you get 60 V across each lamp. That means both of the bulbs will shine dimly or if they’re LED, they may not shine at all. If one bulb were to burn out, the other would also stop working. To get both lamps to shine as bright as their designed to shine, you’d have to essentially run a new 240 V circuit. Therefore, it is unrealistic to have this sort of circuit in a residential setting.
@@mikejohnson3873 If you wired across the 2 hot phases you would be able to run a 240v rated device. I understand this is possible in the US if your installation is set up with the correct sockets etc. I have heard mention of this on other videos but had not fully understood how you could get 120v and 240v until I saw this video.
I am from the UK where we have 240v single phase domestic wiring in which the neutral carries all the return current back out to the street.
For 3 phase commercial systems each piece of equipment would take all 3 phases and would usually have balanced loads (with minimal neutral return current) so sharing neutrals would be less of a problem.
That was an amazing explanation, I would only add one small part. At the transformer, the neutral creates the 120v by having the return path directly in the middle of the 240v transformer wires. And, explain that between the red and the white, you get 120 differential volts, but between red and black you get 240 differential volts. At any rate, that was an amazing explanation and I'll do a better job now of planning circuits in the panel of most used circuits so that the most used circuits are better balanced in the panel.
That was a fantastic explanation !!!!!! thank you for taking the time to do this
As a long time educator, my compliments on a well illustrated and commented presentation.
The "on the fly" illustrations were logically and graphically informative, and well explained.
You get A for this assignment.
That is the best answer I have ever heard. Best teacher ever.
I heard he is married ...
Absolutely brilliant teacher. Wish I had a physics teacher like you in High School 55 years ago
Nice. Nice to see you added the fields and discussed about them. They are a growing significance in PCB Design and Higher Speed conductors as well.
Thanks !
The video seemed cut short a bit. Would have loved for you to spend a little more time on the flow in the neutral when you have unbalanced 120V loads between L1 and L2 and also touch on what would happen to the voltage of L1 and L2 if the neutral to the transformer was lost when the 120V loads were imbalanced. I know the answers, but would drive the point home while reiterating the importance of torquing conductors properly.
There was a house fire across the street from my house one time. The fire department cut power to the burning house and inadvertently opened the neutral to my house. The effect was expensive as I looked back and my house was very bright because of the unbalanced load now running through the lights. I lost a sump pump, a transformer controlling the thermostat for the furnace and a tv that night.
This video is excellent and right on the mark. Any comments regarding getting shocked while working on a neutral are just moronic, what are you doing touching a circuit with the power on? You have no way of knowing if the 240 circuit is running balanced. You cannot touch a neutral with power on.
@@finky555 Well, you can. Once?
This video and explanation is incredible!!!! Thank you, thank you Dustin!!!! These videos are a treasure to everyone who's trying to create a place for themselves in this world!!! This is true solidarity brother!!! I've always asked my teachers to explain some version of this...I probably wasn't asking the question the right way, so I never really got an explanation that was satisfying. I've done AC Theory and we've calculated balanced and unbalanced loads - I can do the math without too much trouble, but the "why" of it all never clicked until now! The electron and field/wave canceling each other out makes total sense, and the idea that the current will travel back on the neutral to get to the opposite pole completely makes sense now. Thank you!! Please, please explain why there is no current on the grounding conductor when there is current flowing on the neutral when the load is unbalanced?
Except it's partially wrong. The "electrons and waves" are not "canceling each other out." During unbalanced loads, the neutral carries only half-cycles, first in one direction and then the other. Current is not flowing in opposing directions on the neutral wire. In the balanced circuit, the neutral wire is completely irrelevant. The two lamps are simply in series with 240v across them..
That was so enjoyable to watch cause you are so honest and natural about your explanations!
It's great you like it, But Don't take his stuff too seriously.
His explainations are filled with errors.
Old electronics tech here - great basic theory. I'm sure some folks will appreciate your effort. Thanks!
The neutral wire is often confused with ground wire, but in reality, they serve two distinct purposes. Neutral wires carry currents back to power source to better control and regulate voltage. Its overall purpose is to serve as a path to return energy.
To make the path easier to flow through basically right?
Actually positive wires carry current back to the source. Neutral is for AC. Therefore the current goes back and forth. Often, neutral is connected to say the frame which is then grounded.
Neutrals do not regulate voltage or offer control
@@rx7addict I think if the neutral is grounded it kind of helps to stabilize the voltages.
@@xxuncexx yes but that’s not the neutral itself. That’s an element added to the neutral to provide a ground reference
For me the easiest way to always remember that "yes, current does flow through the neutral" is that any two-pronged plug won't ever work when plugged into an outlet that's missing its neutral wire connection.
Half the outlets in our apartment are wired so horribly (swapped hot/neutral, missing neutral, no connection at all, etc) that it was a guessing game when I moved in. I wish I'd picked a different unit but this one's lease had already begun so I had no choice...
wait what? you think that current will flow through a single wire depending on what the outlet looks like?
A few fun facts somewhat related to this:
1) In most sparsely populated rural property power is delivered in high voltage buried cable from the power pole to the step down transformer by the electric meter. In my case is 7.5kV single phase via a unground coax cable. From what I infer and research it is called single conductor despite it has the aluminium center core and a outer conductive shield, the shield does not carry the return current. Instead, the earth does despite of its high resistance which is feasible because of the high transmission voltage. This scheme is called single-wire earth return.
2) The step down transformer converts this single high voltage hot leg of 7.5kV down to two hot legs of 120Vac with one shared neutral. The return current of the primary winding travels via earth back to the substation.
3) Power generation stations and the power transmission out of them do not use a neutral because they is done by 3 phase. 3 phase delta has 3 hot legs and no neural.
4) While most residences use only 1 phase AC, they are derived from any one leg of the three phases. Because of this, a 3 phase wye power conversion must be involved.
The return current on the
V Sohn. You are wrong on many aspects of your comment. Old underground cables used to have the neutral exposed, which, over time decayed. Newer cable has the neutral jacketed. Nowadays, most distribution circuits are a Y system, meaning they have a neutral. The neutral is a solid connection hooked to the Xo bushing on the low side of the transformer. All 3 phases and the neutral are hooked together internally in the transformer. On a delta system, there is no return or neutral wire. These systems are dangerous, due to the fact you can literally ground one phase in the system and it will not trigger any protection or relaying on that circuit. Delta systems are not preferred due to the safety factors compared to a grounded Y system.
@@kenchiison4570 The thing is smart people always be aware what they don't know, and the opposite think they know it all. You are seeing things from under the rocks that is the universe you perceive. Read my comments more careful as why I think delta three phase is use for long distance transmission. Delta transmission for thousands of mile requires 3 conductors, while wye requires 4. It does not take Einstein to figure out which one to choose. Neutral and ground is not a high power very long distance (as often interstates) electricity transmission requirement.
Neutral and ground is a local last mile, if not last hundred yards thing. Tell us what is your professional credential. I am not a linesman, but I am a EE despite high power and electrical distribution is far from my expertises.
@@maestrovso .If you're worried about cost, you would just convert to DC and only have 2 wires. Look at your transmission structures. Up on the very top. Usually 2 static wires up there. Used for lightning protection and sometimes have a fiber optic cable in them. Usually tied in to the substation and a pole ground at each structure. Even if it's a delta. You can have a 480Y or a 480 delta. The equipment will function the same. Which one would you prefer?
@@kenchiison4570 You are so out of your depth that it shows. Please when you see those high tension transmission line steel towers next time count the number of cables on them. If there are three they are delta. delta and wye both are user for electric grid, and they both have their uses. I am talking about power grid distributions that is tens of thousands of volts.
Like I pointed out, you view of the system is imprisoned in your little sphere of your myopic view.
@@maestrovso No 5hit Sherlock. 3 conductors but there is still a static wire above, usually. The point is, whether it's delta or wye, it usually has a static wire above for protection, and or, communication.
Thanks so much sharing the partially results of your wonderful education to public, I personally learned alot, please keep up the good work this was excellent explanation of electronic diagrams 🥰👍👍👍
Really well done. You need to spend a few more minutes on imbalance loads. You might want to discuss increased resistance in a ground path at the same time. I’ve seen some interesting ground energy flows in commercial building installations where something had broken or been miswired over time. It really messes with telephone systems and computer networking.
Ground loops will do that. That's why, per the National Electric Code, the system's main bonding jumper (tying the neutral and ground together) exists at one place only in a grounded system. Impedance of the ground grid back to the source should be as low as possible to allow protective devices to quickly operate during a line to ground fault.
Really interesting to see a description of split phase operation and complications. Also interesting to see how load balancing is an important consideration even for domestic installations.
Dad was a master electrician. Damn near short of an electrical engineer. He could build a circuit board to do just about anything. He taught me a ton but there is so much more to learn.
He always laughed when I got (oh and I still do), confused on three way switches.
I also remember him talking about balancing out large starting loads like motors or pumps. He said at the start of the motor it’s at its least efficiency. If you could (forgive me I can’t remember the exact terminology) balance the startup of the motor, you would save money in the long run on your electric bill. I asked why there isn’t a balancing device built in. He said it comes down to cost.
He passed in 2019. I have so many questions now. I almost became an electrician. I missed the apprenticeship by one year. They never offered it again at GM.
THANKS! I enjoyed the lesson.
As a DIY hooking up a 240V well pump and a 240V baseboard heater system this video solves all my potential questions. Thanks...
It’s red leg and black leg. There’s only one phase. Great video! I just get bugged when people refer to A phase and B phase. It’s single phase.
It’s split phase with centre tapped neutral .
Did you just break down Ohms law, power calculations and the physics of electricity in under 25 mins AND manage to squeeze in a rudimentary Thévenin’s equivalent problem for good measure?!? I believe you just did. Very well done sir. (*starts slow clap*)
On a serious note, you should consider teaching circuits at your local college of engineering. You would be a breath of fresh air for all the aspiring EE’s, AE’s and ME’s.
100% agree with this comment, you're better than most of the elect engr profs i had 30 years ago...
@@joem6859 My two profs I had for my electrical classes/electives for my aerospace engineering degree were fantastic. But... they did seem to forget that we didn't remember 100% of everything previously taught to us about electricity. lol
@@j36606 Exactly how is he completely wrong? His explanations fall in line with everything I’ve been taught and experienced.
@@neogator26 I somewhat agree with the other poster that some of his explanation is incorrect. I'd say he's definitely wrong regarding the neutral "canceling current and waves" because of opposition. That is not happening. The neutral carries half-cycles only. First, in a "positive" direction and then in a "negative." So, unbalanced current on the neutral is either flowing into the transformer or away but not flowing both directions at the same time for cancellation.
@@j36606 I'm not sure which specific explanation you're referring to, but I definitely disagree regarding "current and waves canceling in the neutral." That is definitely not happening in a single phase system..
Even with a balanced load the current is still flowing through the neutral. You explained that with the 10 amp -2 amp=8 amp explanation. You measured 8 amps because 2 amps canceled due to the "out of phase" condition. If you have a balanced load the same thing applies. 2 amps cancels 2 amps because they are out of phase. It is a meter issue. The current is still flowing through the neutral, but an ammeter is incapable of measuring it because it is out of phase. For measurement purposes, the phases cancel each other, but the current is still flowing through the neutral.
You taught me something new today. I'm thrilled. Thank you.
I thought the electrons didn't so much flow through the medium as vibrated back and forth and it was the electro-magnetic field that delivered the current to the load.
Yes, you are correct. The charged particles vibrate and the wave passes down the conductor..
I think when electricity is taught it is treated like the flow of water as a basic understanding. A physicist has a deeper understanding of magnetic fields etc.
@@fornife5004 Yes, precisely. Molecules of water leaving the pump outlet, traveling through the closed loop, and then returning to the pump inlet. It's a good analogy for a mental picture and for basic understanding. But, it's only an analogy..
The neutral carries the unbalanced load in a 3 wire circuit. The returns coming off the bulbs to the neutral bar are technically not neutrals - they are return circuits.
You still have an imbalance on a single phase load. 2 legs of 120 volts. You will see it if you have a damaged neutral on a single phase system. One leg will shoot up to say 160 volts, while the other leg goes down to say 80 volts. Neutral is a current carrying conductor. Current is amps. Amps kill you. Voltage doesn't matter.
After years of not "getting" it. Brother you made it make sense. Kudos!
Nice presentation. I'm not an electrician, but have studied electrical theory out of interest, and the key fact that I took away from basic electrical circuitry a few years ago, was simple "the neutral carries the unbalanced portion of the load, back to the grid". During this presentation, I was waiting,...waiting,...waiting for your example,...and sure enough,...10a - 2a = 8a going back out to the grid !! Thanks you for such a thorough demo !!
I think the next video should cover grounding a neutral bar to add resistance
Lol what?
More importantly than pre-drawing it, you need to have set a background color that isn't the same color as the neutral! I get it, you want to use the standard wire colors, cool. But the very very white wire on the very white background doesn't work.
Could have used grey for the "grounded conductor"
@@Darenator1 what is Dustin doing in the video
Thank God for this video! Thank you for posting this. I've been trying to make this point for years on certain YT videos, but AC people seem to be confused.
One of the best explanations I have ever seen. Thank you
My respect for Nikola Tesla just increased further.
Great explanation, now take it to the next level and explain why a broken neutral is bad and can fry shit. You started to head that way with the unbalanced loads.... remove the neutral and what happens? :)
a beautiful explanation. it solved my problem to use a single 12/3 wire for kitchen microwave and kitchen coffee maker on two different outlets without causing overload on neutral. cool. thank u.
I just found your channel. You're a bad-ass teacher. This video taught so many things that a conventional educational video wouldn't even know needed to be explained.
That was the most comprehensive explanation of the topic I’ve ever seen! Awesome job!
Dave W_ master electrician
My house (thanks PG&E) had no neutral connection to my electrical panel for 4 months. The behavior was a bit weird from time to time but everything worked. It’s fixed now but in hindsight it was friggin dangerous. From your video I think it explains the behavior. Thanks.
You just blew my mind. I’m an electrical contractor. I’m 29 so I still have a lot to learn. This just upped my game thank you for your videos 👏🏻
Hopefully it also ups your safety.
@@dustinc1289 The more knowledge I acquire, the better I become at my job. Naturally this makes me safer 🤙🏻
LOVE your explanations!! Even the math geek in me is happy!! :)
Short. With split phase, two equal loads are needed.
With three-phase, three equal loads are needes. Then no current flows through the neutral conductor.
But whenever there is an unbalance between the loads, the balancing current flows via the neutral.
Without a neutral conductor, the voltages are distributed differently across the loads.
Years ago I pumped a lease and it I was told upen delta . I was working a power plant also at the same time and I asked the fellows in the electrical department and they never heard of it as I was having problems at the lease with motor . The ground was broken on the primary. REA was blaming the shop that built the motor , blame game . I found the wire broken and called REA coop they fixed the problem finally. What a learning experience
I think the biggest thing that confuses people is taking that all “electricity” is current.. hence the confusion of current source versus voltage source stuff like that.. once people get just the basic idea of what voltage actually is compared to what current actually is, i.e. talking about fields, versus the flow of electrons, makes everything so much easier to understand!
Getting beyond that comparison to water the most people are taught to compare it with, and have that stick in their head. Makes actually learning and understanding stuff a lot more difficult.
You have such a good balance of bringing in people that I’ve only worked in the field, as well as people that might be engineers, it’s a really good balance and I appreciate that very much!!
We definitely need more of this in electrical, HVAC, etc. etc.
Current is the real physical parameter of electricity. Technically, there is no voltage. The final form of Maxwell's equations has no voltage in it. Now this doesn't mean that the concept of voltage isn't useful--it's incredibly useful. But current is the key.
I love the way you explained this. Thank you for your effort and time