I see that most people benefited from this explanation, which is good. My explanation, when teaching electronics, is to start by explaining how an AC motor works. Then you can see what is needed to start it (and/or run it, ie make spin). Then you can understand what the capacitor must do to make that happen. This forms a better understanding of the start cap, run cap, and motor as a SYSTEM and ties these components together. Then when the question arises as to what the symptom is when the caps fail, they need no explanation, because it is obvious. Thanks for the video. I am always impressed by people who share their knowledge and experience. Keep it up!
Great video, thanks for the info. I'm a homeowner here trying to educate myself to make sure my HVAC contractor is being truthful in the "up sell items" they are trying to get me to guy. Now I understand what a "Hard Start Kit" is, and how it fits with the overall design. Your explanation confirms the measurements the service tech gave me, so thank you! I'm pretty sure I'm not being ripped off this time. BTW, I am an electrical engineer, and I chuckled at the "dig" at the end of the video! At the same time, I've had too many techs and contractors over the years who obviously didn't know what they were talking about, so I appreciate this course and hope the folks who attend can help their customers better in the future. I'll never forget the one technician who confidently told me that "Amps and Watts are pretty much the same thing", which didn't boost my confidence at all. 😅
This was well explained. Coming from the engineering side, about a year ago I started looking for a simple way to calculate what size cap is needed in PSC and CSCR motors. I made a little headway by looking at simplified RLC circuit models. It was enough to realize that when inductors like motors are paired with capacitors, they get a kind of 'tune' that is specific for the frequency of incoming power. If one replaces a cap with the wrong size, expect the circuit to be tuned at the wrong frequency, with unpredictable and often bad outcomes. As you say, relative current flow down the two windings and power factor can dramatically vary depending on the capacitor chosen. My effort to find a simple solution hit a bigger road block when i discovered that power factor and motor inductance vary with rpm, and of course there is the usual tradeoff of starting torque vs full load efficiency considerations. I believe most new motor designs these days are practically tested in the lab with various capacitors, ultimately leading to chosen capacitors that balance power consumption, motor longevity, cost, and reliable starting. There is no easy formula. Any movement away from the design is not likely to end well, if only leading to lower efficiency or poorer motor survival.
Once you get past the starting function, run caps are selected for the best power factor, i.e., most efficient, at the design load. To me, the run cap and aux winding form something of a tank circuit, like are used to tune radios. Grundfos had a good motor book on their website. I believe it is still out on the internet, even the internet archive, but they've organized their "education" so that it isn't readily locatable on the Grundfos website. From that book, I learned the cap is chosen to create as spherical a magnetic field for the motor as possible. When the cap is wrong, the field is elliptical and the non-circular part is dissipated as heat.
@@jkbrown5496 yes using a curve tracer can really help find the best cap too the data sheets are helpful but you would be surprised still how much u can see with a curve tracer just from the shape of the circle that each cap gives you
@@davidknightaudio934 Having to calculate power factor and start/run caps in HVAC doesn't inspire the same confidence I have in, say, a third-order LC crossover/bandpass filter. It's not that capacitors change fundamentally, it's just the amount of variants in manufacturing that can share one data plate. I suppose that is why some people just stock turbo caps on the truck, and why I tend to love good tolerances and high voltage ratings. And, all my facilities with 3Φ power for HVAC. 😁
If only the impedance was fixed. But at least your dealing with a 60hz signal that doesn't complain about parasitics. One way to test, off the top of my head, is to use two probes of a scope. One with voltage over time, the other current over time. Adjust the capcitive component until they line up. I have always though resonance to be that simple. Align the current and voltage components.
I’ve been explaining this to my technicians for years and few seems to get it, so I hope if I show them this video, they will finally understand. THANK YOU FOR DOING WHAT YOU DO, AND KEEP UP THE GREAT WORK!!!
Based on your experience what would you say is the life expectancy of a hvac cap. Would you change a cap at certain intervals? yearly? every two or five years?
I work in the pool industry. I have attended many educational sessions by the manufacturers, and have never heard an explanation about capacitors. I have searched for simple concise information for years, and UA-cam just said "here you might like this". I have replaced many dead capacitors on pump motors. This video gave me a better understanding. Thank you.
Outstanding! I have been teaching HVAC for 30+ years and never thought to compare a capacitor to an expansion tank or a balloon. That is the best analogy I have ever heard! I will use that from now on!
For your "third hand" example for the start windings, instead of the "pinwheel" analogy, I like the bicycle pedal/crank analogy. If the pedals are straight up and down, it is very hard to get them turning, but a third pedal (phase shifted) helps get it going and then the rotational inertia keeps things going.
Very good....let's go further.....yes, when a pedal is straight up and down it's difficult for your legs to rotate the sprocket ( force FORWARD or BACK), but a third pedal located at 3 or 9 o'clock helps.....great visualization that you propose here !!!
Better to just tell it like it is, show magnetic zones and explain that if they are exactly opposite each other, that this just cancels each other out, while if the next field is closer to one of them than the other and then shifts again to repeat for the next field, it induces motion from the magnetic attraction.
I was thinking it would be simpler to use 3 cranks spaced 120 degrees apart. To be more blunt, for the cost of running 3 conductors to residential buildings instead of 2 the appliances would be cheaper, more efficient and more reliable. There's a significant cost for utilities in rural areas, not where the lots are under an acre. The cost to paste 3 phase inverter drives on a single motor is more than the cost to build it right the first time.
I’ve been an HVAC service technician for two years. I just want to thank you guys for all the videos that you put out. I’m sitting in my bathtub right now having a couple beers watching ya!! lol
I’m a Retired Claims Adjuster who specialized in AC “lightning” claims in the seventies when the first batch of home AC units began to wear out. If a tech saw burned wires, they declared lightning damage, obviously because ONLY lightning (not LRA from a mechanically failed unit) could burn wires outside the compressor. I am proud to say I answered almost every question the teacher asked correctly. I am also an amateur reel to reel tape machine repairer, and bad or dying motor run caps are a chronic issue on machined 40, 50, and 60 years old. I took electronics in High School. I find electronics fascinating, even though I specialized in Law and Litigation in the claims business. Very useful presentation, thanks!
As a retired electronic technician, this was very interesting! I really like your way of explaining caps. I eventually developed techniques of troubleshooting and became a very good troubleshooter. It was like you said ....you have to throw a lot of teaching methods, theories, myths, etc out the window and put your mind to work...to work in a way that helps you to understand what you are working on to find the problem quicker and know what to go to first. I've always told people that working with something that you can not actually "see" (electricity) , it can be very challenging!...lol
You and Bert have taught me more than school ever did, two years into the field and I still religiously watch your videos. Great job I wish our weekly meetings we’re more in line with what you do!
As a controls electrician, I troubleshoot machine controls, in manufacturing plants mostly 3, phase circuits but sometimes 1, phase fans, and small motor equipment, this explanation was the best I’ve heard.
When I went solar, I pulled the hard start kits from both of my HVAC units and replaced them with Soft Start kits from Hyper. The inrush current at startup is significantly reduced and much nicer to my solar controllers. When I had my yearly tuneups done the first time after I installed them, my HVAC guy said he was really glad when he sees them. The units he had installed them on haven't had a failure since he started using them. That was 12 years ago, never a problem here. He still says he's not replaced a compressor on any unit with a soft start.
First off....as a non-AC tech (I actually do IT), I love these video's as I learn how my own AC works and as I troubleshoot issues, etc. Second.....micro-ferrets. Love it!
its amazing how many technicans are clueless about all of this. I am an engineer- and own a small AC company and I hear it ---"we tried a bigger cap to start the compressor". ==but a huge capacitor is not going to make a bit of difference. Its the phase shift- that allows it to start. A 3 phase ecm motor changes the frequency to start it and you can run a 3 phase motor on single phase with a phase converter. I think a class for basic electronics should be created and taught---as part of nate or even licensing because customers are charged for all this craziness. Great video.
Capacitors increasing voltage: A person can easily get this conclusion if they measure the A.C. voltage on the input to a rectifier with a capacitor across the output of the rectifier without a load. In North America the A.C. line voltage will measure using a DVM at something near 120 volts A.C. while the D.C. side will read the highest voltage reached during the A.C. cycle which will be 169.7 volts D.C. The idea of A.C. RMS voltage is the same number as an equivalent continues D.C. voltage that would provide the same electric Power to a purely resistant D.C. load. A purely resistant heating element would be expected to produce the same heat from 120 volts A.C. or 120 smooth D.C. Really liked your lecture! Good engagement with the students!
I had a 3750 sqft home (Chicago suburb) with 2 furnaces and 2 central air units. The Rheem condensers were 3 ton & 2 1/2 ton. Walking past the condensers I noticed one of the units was hummimg but not running. I took a rubber hammer and tapped the side of the case and the unit started running (I did this twice in 2 weeks). The units were 10 years old ( I bought the home new and these were installed new). Having a lot of experiences with oil filled motors, I knew there might be a bearing wear issue and when the unit stopped in the wrong place it would not start. I installed a hard start kit that I got with a bunch of electrical parts from a friend. Four years later I sold my home and it was still working, units were 14 years old. The furnaces were Bryant 90 plus and one did need a repair in that same year, but it was only a relay and sensing element. No other problems in the 14 years on those units. Thanks….Jim PS….my current new ranch home has a Trane 80 plus furnace (builder sub installed) and a York a/c system with condenser (a licensed friend & I installed) running 19 years without any problems or repairs.
At around 9:20 you mention that the start winding is “always in place” and that it is not disconnected. Just for your viewers, some single phase motors do disconnect the start winding via a centrifugal switch inside the motor or externally with an electronic Start Switch like a Stearns SINPAC. Great video! I didn’t know the compressor motor left the start windings in play.
I found the video interesting and learned a lot on how the capacitor is used to commutate the motor in a single-phase system. The one word of caution is at the end of your video you talked about plugging the cap into the wall and pulling it out to see what voltage you would get. This is fine on a non-polarized cap like a starter cap, but you mentioned an electrolytic capacitor, which is polarized and will explode if you plug it into the wall voltage. Polarized means it is mean for a DC voltage and will have a "+" symbol for the positive terminal. I' one of those electrical engineers you mentioned:)
False; Go back and review; he mentioned electrolytic START capacitors, which by definition, are non-polar... Hopefully, someone viewing this video knows the difference. Yes, you are absolutely correct to warn anyone NOT to try this with a POLARIZED (DC) capacitor... Most start capacitors over 100µF are non-polar electrolytics (rated only for intermittent duty [they heat up rapidly from the IR losses]) Mr K L (technician and engineering background).
I would love to see a follow up to this adding in potential relays and current relays . This was a great way to hear this and made sense for me. Thanks hvac school
Hello Bryan, Great class. I went to a two year HVAC coarse years ago. It took a long time to figure out capacitors. You did a great job explaining this. I do happen to agree with Nova Air about current leading the voltage.
I like the analogy of the ballon or the bladder tank a pump, I think it is one of the best analogies to clarify how a capacitor works in the circuit Great job Bryan as usual! and you got really nice interactive techs over there really funny to see Bryan's excitement @26:00 when he talks about hooking up a capacitor to your outlet
These balloons can develop negative pressure so a bladder restriction would represent it best. Electrons don't pass through them just as water or air wouldn't pass through the bladder, but can affect the other side in similar fashion. And if subjected to too high a pressure (or voltage in the case of the capacitor), thar she blows 😉
Or a plumbing expansion tank. With a backflow preventer and regulator, the supply will only provide 60psi (for example). In a closed system with all faucets closed after just running hot water, the water heater will fire and increase the psi from heating the cool water that entered the water heater tank while the hot faucet was on. The expansion tank is normally pressurized to 60psi, but the expanding water pressure will push the diaphragm allowing water to flow into the tank (let's say gradually increasing pressure to 65psi instead of 90psi without a tank). This extra pressure is then released when a faucet is opened and the system returns to 60psi when the faucet is closed. However the role of capacitor for a compressor and role of expansion tank in plumbing are totally unrelated.
I contributed to New Age Neon, the standard handbook for Neon sign workshops. Managed the biggest Neon sign factory in the southern hemisphere and contributed to the understanding of Sprites and associated unusual lightening phenomena. I never came across anyone who valued the Right Hand Rule: Force, field, flow. We caused beer signs to illuminate without electrical contact, only field. The lack of electrical engineers understanding of field caused regulations enacted that caused millions list to fires and deaths too. It is important even at ten amps at 60 Hertz. We were handling 10,000hz. And 18,000 V at three amps. We used radio waves in testing too.
From charGPT, In the start sequence of an AC compressor, a capacitor is used to improve the compressor's starting performance. Specifically, a start capacitor provides a temporary boost of electrical energy to help the compressor motor start more easily. Here's how it works: 1. Starting Torque: The capacitor creates a phase shift in the current, which improves the starting torque of the motor. This helps the motor overcome initial inertia and get up to operating speed more efficiently. 2. Smooth Operation: After the compressor starts, the capacitor usually disconnects from the circuit (in the case of a start capacitor) or remains in the circuit to improve efficiency (in the case of a run capacitor). This helps ensure smooth and efficient operation.
Great video and explanation. A capacitor in this application acts much the same as an accumulator in hydraulics, or a pressure tank in plumbing. All of these items can release a lot of energy(pressure/volume) fast, when needed. Cheers.
You guys are awesome! I just started teaching HVACR at a community college in North Carolina, and I share lots of your content because it's well-explained and you have some hilarious moments as do we! Keep up the good work.
I loved this video, I learnt so much, as an older technician I’m always learning. I use hard start capacitor kits to replace the current relay and start capacitor with great success I have seen them last 12years then fitted another and away it goes again. I almost never use the original start components and have kept many compressor running for many years , I have been using them for about 15years now. I never get caught without starting components. You can’t save them all but most you can.
@@davidknightaudio934 that is your opinion but I have proven this works over 15years, I think you should always have an open mind, just because it has always been done a certain way doesn’t make it the only way or the best, always strive to do better. All the best
Bryan ..I have always thought of a 3 phase motor as a 3 cylinder engine...each phase firing 120 degrees out phase. If that helps ..?? Very well explained for everything else, SIR!
Excellent definition of what caps do and how they do it. Like he says, its not magic and its not terribly hard to understand and you dont have to go 6 layers deep to get the gist of a caps function.
Fantastic video!! The presentation was clear and informative. If I ever decide to become a HVAC tech, I would want this guy for an instructor. Would like to see a class on these soft start units that are advertised for RV a/c units to reduce demand for amps at compressor start up. Throwing it out there for a topic of discussion in case you wanted input. Thanks!
This is your best explanation, I heard so far. Thank you so much for using the analogies, it made a world of difference for me. I finally comprehend it fully. The analogy you used was something I was familiar with the expansion tank for a water pump, I actually replaced the bladder on one tank, and had to fill the air surrounding it to 30 lbs to keep it from rubbing against the inside surface. So yeah made a lot of sense.
So, a capacitor works by transferring energy via the electric field. Typically, it blocks DC and it takes AC to transfer the energy (again, through the electric field) from one side of the capacitor to the other. A capacitor also causes a phase shift in the applied energy, where the current in a capacitor begins to lead (or come before) the voltage in the circuit. Inevitably, you will find circuits where there is a large amount of inductance involved. (an inductor transfers energy by a magnetic [or electromagnetic]) field. This typically is found in motors, which exhibit the properties of an inductor. And in an inductive (typically, a motor) circuit, it exhibits the opposite properties of a capacitive circuit; that is, in an inductive circuit you will find that the Voltage in a circuit begins to lead (or come before) the current in a circuit. Now, it is important to realize three things, 1) that if you have an inductor (typically, a motor) in the circuit, and a capacitor in the circuit, that essentially, to the extent possible, (depending the amount of capacitive reactance, and the amount of inductive reactance in the circuit) they will tend to cancel each other out; and 2) the most actual power transfer takes place when the current is 100% in phase with the voltage; and 3) that happens when the capacitive reactance of the capacitor cancels out the inductive reactance of the motor. And then, there is no resulting phase shift. Consequently we hit that golden point where as much power as possible is being transferred from the source (in an AC, usually 240 VAC) to the load (usually an Air Conditioner or fan motor). Other higher voltages can be used where more power is needed to be used, but while higher voltages are common in industry, they are not so common in home use. Above, I mentioned Capacitive Reactance (typically called Xc ... [usually pronounced "X sub C"]), and Inductive Reactance (typically called Xl ... [usually pronounced "X sub L"]). There a formulas for both of these, and deeper explanations for both of these all over the internet. But when Xc = Xl ... there is no phase shift, and you have maximum power transfer from the source to the load. One additional point. In the starting of a motor, the amount of Xc needed to cancel out Xl is greater, and all the time changing during the 'speed up' phase, until the motor reaches full speed, where Xl levels out. That is why there are two different values of capacitors used, 1) for the "start" circuit, and 2) for the "run" circuit. Xc for the 'Start' circuit is typically optimized for the startup phase, and Xl is typically pretty close to where it needs to be for the "run" phase, thereby providing the most efficient of both worlds ... start phase and run phase. These are basic electrical as well as electronic principles. Sadly, many never grasp the meaning, and come to an understanding of why. And I have to admit, it took me a long time to come to that realization. But when the 'Ah Ha' comes ... you will be forever improved at your particular tasks, whether electrically or or electronically. And, especially, in a motor circuit, you will understand what the actual purpose of that 'start' - 'run' capacitor actually is.
All of that is true, however You’re not making the difference clear between a capacitor that corrects power factor with a start capacitor. Start capacitors in a motor are only used for the phase shift on the start winding. Their purpose is not to reduce the VARs of the circuit or increase power factor. Which is what he explains in the video. In fact if the run windings are at 100% power factor, the start capacitor will increase the VARs for the start winding because that is what causes the phase shift and what is necessary to get the motor spinning
@@benheaton3728 You are correct. I didn't mention power factor, in the sense that I didn't name it. But it does have to do with that phase shift in the circuit. That phase shift occurs when the capacitive reactance isn't quite balancing the phase shift in the other direction due to inductive reactance. In that case, magnitude of Xl does not equal the magnitude of Xc, and there is a resulting phase shift (because it is not completely cancelled). The power factor is a single mathematical description of that resulting phase shift where PF = COS(Theta), which says that Power factor is equal to the cosine of the resulting phase angle. If I remember my theory correctly, when PF = 1, it is in phase, and the most energy is transferred from the source to the load.
There is never energy transferred directly from one side to the other. When voltage is applied to one side the opposite polarity induces voltage on the other side of the capacitor. So imagine a positive voltage applied to side 1. As the voltage ramps up in the run coil and the magnetic field is induced, side 2 of the capacitor charges through the voltage force pulling or pushing on the start coil, creating a second magnetic field.
Great video - truly my new favorite YT channel. Quick question - if you replace a compressor on a unit that has a HSK, why would you keep the HSK in the system? Isn't the HSK only installed due to the compressor being on its last legs so when replaced, the HSK would no longer be necessary?
Fantastic explanation and all the metaphors were spot on!!!! Thank you for sharing this knowledge and approach to learning how HVAC systems work! Great job Bryan!!!
Can't complain -- it's a fairly good video. I sort of like how they embrace what they 'think' or 'visualize' is happening over what's actually happening. Myself, I have a good electrical engineering background, but know nothing of HVAC units... When he discusses the wheel of fortune wheel and the 'third hand,' I chuckle because it gets the idea across, but I think it's missing a key component. 1) Most people know that magnetics either attract or repel, depending on the poles. This is the fundamental working force behind a motor, you construct a system such that the repelling / attracting force of two magnets make it spin. 2) Most people also know you can make a magnet by passing current through a wire. 3) Lastly, most people know the 'pole' of an electro magnet (one made by passing current through a wire) is determined by the direction of the current (i.e. the polarity of the source voltage) What's missing I think for some people, like myself, is the revelation that HVAC motors do not have static / permanent magnets. They instead use electromagnets for both the stationary and spinning sides of the motor. How is one expected to control the poles of the magnets such that it spins, if both sides are powered by a single phase power source? That'd make both sides N at the same time, and both sides S at the same time, locking the motor in place. The answer is the capacitor; a phase shift that makes one side N, the other S with just the right timing to get it moving. Once moving, the alternating periodicity of the power source keeps it moving.
Very helpful information. It’s true, the electronic theory it’s not really necessary to understand what the compressor is doing in terms of the service man. I guess they don’t use the old fashion potential relays anymore. They are designed to take the starter capacitor out of a circuit mechanically. Just like so many of your videos this one gave me good insights in terms of troubleshooting what has happened in the compressor. There’s also a slight difference between a label and the actual value of the capacitor. I liked your explanation about the percentage of difference from the total, when choosing, whether or not to use another capacitor that is close in value.
For ac that is actually not the right symbol for a capacitor as the one you show is polarized so only for DC. The symbol for an un polarized cap is just 2 straight lines instead ( two T instead of one curved)
It is semi common for non polarized caps to have a curved line. While I hate when part of the world use them, its the + next to one of the lines that makes it polarized.
I was going to say the same thing, you are 100% correct, we are talking about 220VAC unrectified voltage here, the symbol with a curve shows polarity i.e. the negative most side. You CAN'T (or at least not supposed to) use this symbol because there is no ground reference (or lowest FIXED negative value i.e. -110VDC). You can't even argue that the wave swings to -110VAC, because in the next half cycle it is now +110VAC and the capacitor would be considered reverse bias polarity for that half wave (and boom goes the dynamite after a few cycles of 50 amps of the dielectric boiling to the explosion point). There is a reason why there are two capacitor drawing types for both polarized and non-polarized capacitors. My skin crawled when he said just stick it in a wall outlet as the example. If that was done with a polarized cap, you now have a deadly firework in your hands when it overheats and explodes from the reverse polarity 1/2 wave cycles. If the cap is non-polarized, as these HVAC caps are, then yes, his stick in it the wall and measure under controlled conditions can be checked and validated as he says. Overall, the presentation is excellent and well thought out, it's just a minor thing regarding the symbol usage of the capacitor that should be tweaked to ensure proper proliferation of the component identification. To anyone saying "the rest of the world"... that is a lovely sentiment, pick up an accredited EE book and then find the section on capacitor identification between the two types, your region may do it differently because... well whatever reason, honestly, no one cares why you're doing it wrong, but technically it is wrong, any EE book on the subject matter outlines these facts and if it is being regionally done another way, that is another topic entirely.
Good video Capacitor used on AC doesn’t have polarity Capacitors doesn’t reduce the amount of current, just de-phase the voltage and current (shift forward the current from the voltage) AC voltage doesn’t goes from 0 to 150 as the video said, in facts it goods from -150 to +150
The capacitor also dictates how much current can get through by its size in micro Farads it fills up on half the wave and dumps on the other half what it has stored with is dictated by its size hence it does effectively limit current
As an electrical engineer, I can assure you that a hard start kit does not reduce start current. It actually increases current a minor amount, but it reduces the spin up time by increasing initial spin up torque of single phase induction motor. By reducing the start time, the high surge current period is shortened. The only legitimate use of a hard start kit is for low AC voltage at compressor either due to low grid voltage or too much wire voltage drop from circuit breaker panel due to long wire run and/or too small wire gauge used to compressor during the high startup surge current. The lower the voltage applied to compressor the longer the motor spin up time and the startup surge current time length. The run capacitor value is selected to provide 90 degrees of current phase shift to the start (auxiliary) winding of motor only for run condition. This provides better motor torque for given AC current while running and also improves the motor running power factor. The run capacitor value is not optimized for motor startup. It is optimized for run state of motor. During startup the motor is highly inductive. To provide 90 degs optimum current phase shift to start winding during startup for maximum torque, the start capacitor would need to be three to four times the run capacitor value. Once the motor spins up, the motor is less inductive and the value of optimum capacitor to start winding must be changed to lower value to provide 90 degrees current shift during run state. Hardstart kits do this with a relay that opens start capacitor connection when back EMF from start winding rises after motor spins up. You will typically see 290 to 300 vac from compressor common to start winding terminal after startup on a 240vac system. If you put your amp meter on compressor common wire and measure compressor current, then put amp meter on compressor run wire and measure it, then start winding of compressor and measure its current. the sum of run wire current and start winding current will be greater than compressor common wire current. How can that be? It is because the start winding current through the run capacitor is shifted in phase by about 90 degrees during motor run condition. For example, common current is about 12A, run wire current is about 10 amps, start winding current is about 7 amps. The result is because 10A run at 0 degs phase reference plus 7 amps at 90 degrees current offset equals 12-amp sum when done with vector phasing addition. Three phase motors have three windings, offset by 120 degrees physically with corresponding 3 phase AC drive. This creates a rotating magnetic field necessary to get motor spinning. Single phase motor has to synthesize another AC phase source to create a rotating field to get motor to spin up. This is done by starter (auxilary) winding which is physically wound 90 degrees offset from run winding and the series capacitor to synthesize the second AC source phase with 90 degrees offset from single phase AC input.
In reading a book about Ben Franklin when he was messing around with electricy he found that he could collect it with different materials in a glass jar. Then figured out that connecting them depending on whether in series or parallel he could increase the amperage or voltage, he call the collection a battery. Sounds more like a capacitor.
Blown capacitors might have a "bump" on top, where the relief valve is located. Side-note: Stand-up refrigerators compressors don't have the "start" winding always connected, only at start time.
@@foobarmaximus3506 No, Freedom Speech is correct; Most domestic refrigerators/freezers with fractional HP hermetics have start 'relays' or PTCs that effectively cut current to the start winding after the start cycle... Mr K L
We have a 14 year old Goodman Heatpump here in N. Floo’da, runs fine, 1.5 years ago a AmRad Turbo200 was put on it when the stock Cap went bad, Now we have a 5-2-1 HS Kit on it, but the Turbo200 has the Orange 🍊 CPT post on it to protect the compressor from getting power if the cap failed, you just put the wire from the HSK to the Orange CPT post instead of the Common post of the main capacitor…!! 22:15. Do you agree?? BTW, You’re a Great Teacher. ✅
ELI the ICE man In an inductive circuit, voltage leads current by 90* In a capacitive circuit, current leads voltage by 90* The PSC motor is a capacitive inductive circuit The capacitor is trying to neutralize the phase shift in the start winding, that was originally caused by the run winding being shifted by the inductive circuit. The effect is that there are more “north and south” poles making the motor more efficient and more powerful by having electromagnetic forces applied at multiple points at any given time.
One of the points that is missed here is low supply voltage during the short LRA that occurs on start up. This is real common, and should be one of the first things to check. I’ve seen electricians run too small of conductors, which causes low voltage on compressor start up. This can also be caused by high resistance connections at the sub panel, the disconnect, the contactor, etc. I have seen this numerous times. The spec is that the voltage should be within 10% the rated voltage, on start up, or what is specified on the unit nameplate. Measuring static supply voltage wii not catch this. Just like checking for power, as the first step of trouble shooting, voltage drop on compressor start up needs to be checked as one of the first tests. Think of a garden hose with 60 lbs of pressure, when it is not flowing, then when the valve is opened, there is low flow, and low pressure at the end of the hose, because the hose is too small. I am surprised this important concept was not covered as a cause of failure of a compressor to start..
Please explain the back EMF and the reason why capacitors have such high voltage ratings compared to the actual line voltage. I don’t think hardly anybody realizes why the voltage rating is so high on a capacitor but it is a result of the induction of the collapsing field
The magnetic field an inductor creates doesn't like current changes. As the current supply to an inductive load goes away the voltage will raise to try and keep the current the same. While this transient spike is easy to contain, the voltage and current get out of phase. A capacitor changes the phase in the opposite direction. You use the two together to align the current and voltage phases to create resonance, and remove standing waves. A simple LC circuit. Remember, you are working with waves. Inductance not only has a resistive element, but also the inductive and campacitive components. The values of each are a function of the primary frequency. This probolly sounds like Chinese, and you will need to learn the math to fully understand it.
@@falsedragon33 AFAIK, run caps are nowhere near resonance. If they were, I think the voltage would rise (resonate) off the charts... [I'd have to calculate the Q, and then there back EMF, which changes it from a simple RCL equation...]
You asked for the symbol of a capacitor. There are several symbols used. I'm not going to try to show them here, some show which side of the capacitor is the outside of the wound foil, for our purposes, it doesn't matter. There are a few symbols to show an electrolytic capacitor, where the polarity is shown. Electrolytics are polar-sensitive, you connect them backwards, they blow up in your face, that's to DC. Often internally, AC capacitors are non-polar, internally they could be two electrolytics in series, back to back, which makes polar devices into non-polar, and as said, sever different symbols are used. Then there are other types that are variable, some are called varicaps, the capacitance is adjusted by the applied voltage, but not in the HVAC business. I could go on and on. What confuses some people are the symbols used for switches, some put them into two categories, electronic and industrial. Having worked both sides, not confusing at all to me, but if one has only worked in industrial electronics, may not make sense. Just to make the water more muddy. Jim
The start winding dosnt get its power from the run winding it does come from the cap it just dosnt pass straight thru the cap the cap charges then on the next cycle dumps its stored charge into the start winding its capacity dictates how much power it dumps into the start winding and the charging and discharging happening at two different times on the sine wave is how it creates a phase change also having a potential relay stick closed can taost the winding but it can also cause the cap to explode other than that you're spot on with everything I'm really glad to finally see someone who knows what they're talking about doing one of these videos so many people who just come up with their own theory make videos and they are wrong
Very well said still don’t know what a capacitor does lol but it gave me a idea of what is trying to do i’ve been doing this for 40 years and that was the best explanation I’ve heard 👍
Thanks as always your content is solid. I know for me the most recent key to understanding how electricity works is how it is created from electro magnetic fields which pushes and pulls the electrons through the circuit and then in the case of inductive load it been creates electro magnetic fields Maybe I missed it but I would love to hear your take on how electricity flows in each circuit from the power plant transmission lines and the service seeds of a building our home. And then last but not least how electricity is consume if you will.
I love listening to you. Your explanations are quite good. HOWEVER, don't use "attractive" force when talking about capacitors, electrons going in one side of the capacitor repel electrons (across that plastic film) and push them out the other side. The balloon analogy is good, but use two balloons sharing a fixed container. When you push air in one balloon, it squeezes air out of the other. As one balloon fills up, it becomes harder to continue to push air in that side (acts like a variable, increasing resistor). You get all that pressure back when you switch to the other half of the cycle. During the cycle, as the voltage approaches zero, one balloon is as full as it can get, creating back-pressure (high resistance to current). When the cycle passes through zero, that pressure (voltage) is released creating high current. NOTE: you get decreasing current while the line voltage is increasing and you get high current when line voltage passes through zero! This is the cause of the phase shift observed with capacitors. Thank you for this excellent presentation!
TFJD: Im surprised you would make this statement knowing nothing about where they are, either in the unit or curriculum. This could be Day 3 for a bunch of kids coming in green off the streets.
Great video. I installed a 5-2-1 start kit on my 4 ton unit. It is properly sized (3.5 to 5 ton) for the unit. You have me a little worried about not using the factory kit. Unit is 20 yrs old and has been running great. Should I be worried?
Not at all. The 5-2-1 brand is the best "fits all" start kit. Trane is the only brand that has specific separate part numbers for the relays and start capacitors, you buy them separately as opposed to the 5-2-1 being preassembled. The engineers at 5-2-1 claim their relays open sooner than other brands thus reducing the risk of overload on the S circuit.
@@briangc1972 - thank you - my Carrier/Copeland compressor has the start capacitor sized for the 1-3 ton 5-2-1 product (CSR-U1) even though it is a 4 ton unit and 5-2-1 recommends the CSR-U2 product. I went ahead and went with the same capacitor that Copeland specs - the CSR-U1 and not the CSR-U2. So I am running as close to the OEM part that is possible it is just that 5-2-1 made it. The start amp drop is a little more signifigant using the CSR-U2 which went from 108amps to 58 amps (I installed the CSR-U2 before looking into the OEM part and realizing I really needed the CSR-U1). The CSR-U1 start up amps went from 108 to 76 amps So not as good as CSR-U2 but not sure what else needs to be considered. Thanks again Brian
@@briangc1972 - thanks for the advice. It’s just disconcerting knowing that that’s not what the OEM part is. I don’t know what the technical details are - pros and cons of using the larger capacitor. Could it be damaging the compressor more than the other one even though it seems to work fine?
Glad I came across this video. I have my home set up with a generator disconnect and want to run my ac with the generator. But my generator doesn't push enough power to start the AC unit. I have been told that a hard start will allow this. But the AC runs fine now. So my question is this. Is there any harm with installing a hard start kit on a AC unit that is running fine, so when the power goes out and I am operating off generator power the hard start is already in place and ready to go? Also what are your thoughts on a micro air soft start kit?
Great video! I have no formal education on A/C and I have not been able to get a good understanding of capacitors from my licensed A/C technicians. I am installing a 10k 30amp generator and would like to know if a soft start is any better than a hard start. I was looking at a soft start from Micro Air which is almost $400 and I'm wondering if it is better for the unit than a hard start. Any comments is appreciated. Thx
I'm old school taught. The theory of split phase is , to me, the function of the capacitor, and is what generates stronger magnetic fields temporarily, to increase the ability of the physical motion of an inductive motor, without overall increase of wattage uselessly expended by the motor. In fact it decreases it. In any electric sine wave there are two components, current, and voltage. The motor typically starts on the current wave, and runs on the voltage wave. In a capacitive circuit the current wave is split away from and precedes the voltage wave. As the current wave reaches its peak the voltage wave is at or near zero. As the voltage wave approaches it's delayed peak, current in the capacitor approaches zero. I wish I could draw the 2 waves as they pass through a capacitive circuit for you, and compare it to the single phase inductive motor sine wave, but you can likely find this in a different video that does focus on 'capacitor start, capacitor run inductive motor'. It has been my experience that a properly applied start capacitor along with the correct (very important ) run capacitor, given the motor windings are close enough in relative resistance , thus designed to implement a run cap. during operation, actually can enhance the performance and increases the lifespan of an inductive motor. With a solid state start relay, you can actually hear the motor kick on to full speed considerably quicker after a start cap. is installed. Same with a mechanical start relay, but it is less pronounced, even though it does much the same thing. The less time you can spend with the start windings getting full current, the longer the motor will last, generally speaking. The start windings seem to be the weakest link in an inductive motor, over time, as they have far higher dynamic power fluctuation when you consider the watts per inch load required to start the motor in day to day operation. Getting those start amps down to run amps as quickly as possible is not only efficient, it is also less stress on the motor windings, as they are subject to expansion and contraction directly proportional to current induced heating and cooling. I would recommend studying split phase analysis and implementation if you decide you want to understand electrical theory in that respect. And I would encourage an understanding of inductive resistance as well. The field of electrical theory can be understood if properly taught, and will be extremely helpful in these hvacr jobs in your distant future. Of course each teacher has their own style and way of understanding this field and what they consider important enough to convey it understandably to the students. I feel very fortunate to have had Richard Deputy as my instructor on this subject in 1986. A very smart man, and a very good instructor. Would that I could be more like him.👍 I learn something knew as often as possible. It's a good feeling when I do, as this is my lifelong trade. And I hope I learn from my mistakes, and try to pay close attention to them. I will not ever know everything. 👍
I like to use mechanical and fluid analogue, where voltage is something like pressure. A resistor is a sponge or constriction. An inductor is a flywheel driven by a displacement pump acting as a motor. A capacitor is a double-acting piston with a centring spring whose spring constant is the inverse of the capacitance. A motor depends on having a rotating magnetic field. Three phases 120° apart in phase and 120° geometrically (in space) makes for a perfectly steadily rotating field. Single-phase makes for a useless linearly oscillating field, like stamping on bicycle pedals stuck at TDC and BDC. A single-phase motor makes an elliptical rotating field (strong in one axis, weak on the other) with the help of a wining that has an angle difference (phase shift) in space and electrically (i.e., in time) that works like pushing a foot forward on the bicycle pedal at TDC. The phase shift is important because if the start-run capacitor were replaced with a resistor or a lower voltage supply matching the original phase, the rotating magnetic field would degenerate into a useless linear oscillating field, just inclined at a fixed angle. In such a case, the motor's impedance appears as resistance rather than reactance (with a little resistance), so it turns into a heating element. (Reactance is what you get when you use a flywheel or a trampoline, resistance is what you get when you drive your hand through syrup, dissipating energy as heat.)
For some reason there were no (0) likes on this video, on my screen? Well i just left one like! It is super helpful to see your videos and I’m very thankful that you took the time to record and post the information in regards to capacitors. I’ve heard a lot of people try to explain what they are and nobody knew what they were talking about. LOL! So it’s great to see you actually know what it is!
Umm, WHUT? 1:15 and before, you're drawing the symbol for a polarized capacitor while these are non-polarized with a symbol that is two straight lines in parallel, not one of them curved which is for a polarized capacitor. Some people might think that because there's a common that this makes it polarized but it does not, that is just a simplified construction method that shares one of the poles of two NP caps.
This really helped me understand cap. function. Thanks. BTW, I am not a sparky by nature. I avoid this art form at all costs. Yet, a bit of basics is handy sometimes.
The opposite phase shift of the two parts causes the measured capacitor voltage and motor winding voltage to appear significantly larger than you would expect. Depending if the circuit is close to the resonant frequency (Xl = Xc) or not, and the Q (resistive loss) it is possible to have higher voltage on one or both component than the line voltage applied across the series combination. (I was an RF Transmitter tech back when tubes were popular so I got to play with big motors AND RF circuits).
Well explained thank you very much. By connecting the phase line to the start coil and connecting the run capacitor in series with the running coil direction of rotation will be reversed. Its long story why i have to but, One time i have fitted by reversing the direction of single phase fun motor and it run continously for about 1 month until i recieve another one. I would like to know how bad is it the fun and what could have happen to it?
It is not designed for that. The run winding and start windings have different resistances, and have different designed running amps going through them. Wiring it backwards likely creates excessive heating in the wrong places.]Hopefully the overload would protect it from damage (unless allowed to repeatedly cycle/shutdown). Likely it overheats the start winding with excessive amps. It might be possible to find a generic fan blade in the 'other-handed' rotation for you existing incorrect motor... check an HVAC supply house.
@@troubleshooter1975Thank you so much i understand now what could have happend. To be clear sir i did that not for expermenting. i was on board ship no spare on board & provision store(fish room) evaporator fan just faild so temporarly i just fixed another fan but its direction needs to be reversed by any means the store has to be saved. Luckly it withstand until we get the original fan.
The symbol you have drawn is a polarized capacitor. By the way there is considered a current "flowing" it is a construct known as DISPLACEMENT CURRENT. This was a consequence of Maxwell Equations. The model we use is i = C dV/dt this is why if V is a sine wave the current will be a cosine wave . 90 degree phase change. Actually electrical and magnetic circuits are grossly oversimplified by lumped circuits. To understand electric effect deeply we need to use Electric and Magnetic Field theory trouble is it is very hard to understand, Hence the notion of displacement current versus electrons flowing.
Thanks for the video just in time for cooling season here in the Midwest. Learned a lot here!
After only ~8 minutes of this video, I'm amazed at how clearly Bryan explains how capacitors function. Nice work!
I see that most people benefited from this explanation, which is good. My explanation, when teaching electronics, is to start by explaining how an AC motor works. Then you can see what is needed to start it (and/or run it, ie make spin). Then you can understand what the capacitor must do to make that happen. This forms a better understanding of the start cap, run cap, and motor as a SYSTEM and ties these components together. Then when the question arises as to what the symptom is when the caps fail, they need no explanation, because it is obvious. Thanks for the video. I am always impressed by people who share their knowledge and experience. Keep it up!
Great video, thanks for the info. I'm a homeowner here trying to educate myself to make sure my HVAC contractor is being truthful in the "up sell items" they are trying to get me to guy. Now I understand what a "Hard Start Kit" is, and how it fits with the overall design. Your explanation confirms the measurements the service tech gave me, so thank you! I'm pretty sure I'm not being ripped off this time. BTW, I am an electrical engineer, and I chuckled at the "dig" at the end of the video! At the same time, I've had too many techs and contractors over the years who obviously didn't know what they were talking about, so I appreciate this course and hope the folks who attend can help their customers better in the future. I'll never forget the one technician who confidently told me that "Amps and Watts are pretty much the same thing", which didn't boost my confidence at all. 😅
This was well explained. Coming from the engineering side, about a year ago I started looking for a simple way to calculate what size cap is needed in PSC and CSCR motors. I made a little headway by looking at simplified RLC circuit models. It was enough to realize that when inductors like motors are paired with capacitors, they get a kind of 'tune' that is specific for the frequency of incoming power. If one replaces a cap with the wrong size, expect the circuit to be tuned at the wrong frequency, with unpredictable and often bad outcomes. As you say, relative current flow down the two windings and power factor can dramatically vary depending on the capacitor chosen. My effort to find a simple solution hit a bigger road block when i discovered that power factor and motor inductance vary with rpm, and of course there is the usual tradeoff of starting torque vs full load efficiency considerations. I believe most new motor designs these days are practically tested in the lab with various capacitors, ultimately leading to chosen capacitors that balance power consumption, motor longevity, cost, and reliable starting. There is no easy formula. Any movement away from the design is not likely to end well, if only leading to lower efficiency or poorer motor survival.
Once you get past the starting function, run caps are selected for the best power factor, i.e., most efficient, at the design load. To me, the run cap and aux winding form something of a tank circuit, like are used to tune radios. Grundfos had a good motor book on their website. I believe it is still out on the internet, even the internet archive, but they've organized their "education" so that it isn't readily locatable on the Grundfos website. From that book, I learned the cap is chosen to create as spherical a magnetic field for the motor as possible. When the cap is wrong, the field is elliptical and the non-circular part is dissipated as heat.
@@jkbrown5496 Thanks, for the tip, I found it, searched Grundfos motor book pdf.
@@jkbrown5496 yes using a curve tracer can really help find the best cap too the data sheets are helpful but you would be surprised still how much u can see with a curve tracer just from the shape of the circle that each cap gives you
@@davidknightaudio934 Having to calculate power factor and start/run caps in HVAC doesn't inspire the same confidence I have in, say, a third-order LC crossover/bandpass filter. It's not that capacitors change fundamentally, it's just the amount of variants in manufacturing that can share one data plate. I suppose that is why some people just stock turbo caps on the truck, and why I tend to love good tolerances and high voltage ratings. And, all my facilities with 3Φ power for HVAC. 😁
If only the impedance was fixed. But at least your dealing with a 60hz signal that doesn't complain about parasitics. One way to test, off the top of my head, is to use two probes of a scope. One with voltage over time, the other current over time. Adjust the capcitive component until they line up. I have always though resonance to be that simple. Align the current and voltage components.
You’re a great instructor! Never give out an answer, always make the class work for it.
I’ve been explaining this to my technicians for years and few seems to get it, so I hope if I show them this video, they will finally understand. THANK YOU FOR DOING WHAT YOU DO, AND KEEP UP THE GREAT WORK!!!
Based on your experience what would you say is the life expectancy of a hvac cap. Would you change a cap at certain intervals? yearly? every two or five years?
@@bwj1158 when its below its manufactured rating usually 5%±
@@cricricri122 Thank you!
Very good explanation of one of the simplest electrical devices that is the most miss understood in the industry. 😮
Depends on the heat environment it is subject to heat kills them over time so in florida 1 year maybe ohio 3or4 years or more ?
I work in the pool industry. I have attended many educational sessions by the manufacturers, and have never heard an explanation about capacitors. I have searched for simple concise information for years, and UA-cam just said "here you might like this". I have replaced many dead capacitors on pump motors. This video gave me a better understanding. Thank you.
Outstanding! I have been teaching HVAC for 30+ years and never thought to compare a capacitor to an expansion tank or a balloon. That is the best analogy I have ever heard! I will use that from now on!
Bryan is an excellant instructor. He is extremely knowledgable and makes it easy to understand the subject he is teaching. He should be paid very well
not really
For your "third hand" example for the start windings, instead of the "pinwheel" analogy, I like the bicycle pedal/crank analogy. If the pedals are straight up and down, it is very hard to get them turning, but a third pedal (phase shifted) helps get it going and then the rotational inertia keeps things going.
Very good....let's go further.....yes, when a pedal is straight up and down it's difficult for your legs to rotate the sprocket ( force FORWARD or BACK), but a third pedal located at 3 or 9 o'clock helps.....great visualization that you propose here !!!
I like the merry go round analogy
Better to just tell it like it is, show magnetic zones and explain that if they are exactly opposite each other, that this just cancels each other out, while if the next field is closer to one of them than the other and then shifts again to repeat for the next field, it induces motion from the magnetic attraction.
I was thinking it would be simpler to use 3 cranks spaced 120 degrees apart. To be more blunt, for the cost of running 3 conductors to residential buildings instead of 2 the appliances would be cheaper, more efficient and more reliable. There's a significant cost for utilities in rural areas, not where the lots are under an acre. The cost to paste 3 phase inverter drives on a single motor is more than the cost to build it right the first time.
I’ve been an HVAC service technician for two years. I just want to thank you guys for all the videos that you put out. I’m sitting in my bathtub right now having a couple beers watching ya!! lol
I’m a Retired Claims Adjuster who specialized in AC “lightning” claims in the seventies when the first batch of home AC units began to wear out. If a tech saw burned wires, they declared lightning damage, obviously because ONLY lightning (not LRA from a mechanically failed unit) could burn wires outside the compressor. I am proud to say I answered almost every question the teacher asked correctly. I am also an amateur reel to reel tape machine repairer, and bad or dying motor run caps are a chronic issue on machined 40, 50, and 60 years old. I took electronics in High School. I find electronics fascinating, even though I specialized in Law and Litigation in the claims business.
Very useful presentation, thanks!
Awesome video, I’m a structural engineer who has 30+ years of building experience and I learned a few things about capacitors i never knew, very cool.
As a retired electronic technician, this was very interesting! I really like your way of explaining caps. I eventually developed techniques of troubleshooting and became a very good troubleshooter. It was like you said ....you have to throw a lot of teaching methods, theories, myths, etc out the window and put your mind to work...to work in a way that helps you to understand what you are working on to find the problem quicker and know what to go to first. I've always told people that working with something that you can not actually "see" (electricity) , it can be very challenging!...lol
Thank you for a professional taught class on engineered specific residential A/C system capacitors ....! You made it digestible. well DONE!
You and Bert have taught me more than school ever did, two years into the field and I still religiously watch your videos. Great job I wish our weekly meetings we’re more in line with what you do!
"Electrical engineers are always fun". Good video. AC folks need to watch this.
As a controls electrician, I troubleshoot machine controls, in manufacturing plants mostly 3, phase circuits but sometimes 1, phase fans, and small motor equipment, this explanation was the best I’ve heard.
When I went solar, I pulled the hard start kits from both of my HVAC units and replaced them with Soft Start kits from Hyper. The inrush current at startup is significantly reduced and much nicer to my solar controllers. When I had my yearly tuneups done the first time after I installed them, my HVAC guy said he was really glad when he sees them. The units he had installed them on haven't had a failure since he started using them. That was 12 years ago, never a problem here. He still says he's not replaced a compressor on any unit with a soft start.
I hear they help with generators as well
When you bring up the balloon idea, it changed how my perception of capacotor forever! Wow. Great info.
First off....as a non-AC tech (I actually do IT), I love these video's as I learn how my own AC works and as I troubleshoot issues, etc. Second.....micro-ferrets. Love it!
its amazing how many technicans are clueless about all of this. I am an engineer- and own a small AC company and I hear it ---"we tried a bigger cap to start the compressor". ==but a huge capacitor is not going to make a bit of difference. Its the phase shift- that allows it to start. A 3 phase ecm motor changes the frequency to start it and you can run a 3 phase motor on single phase with a phase converter. I think a class for basic electronics should be created and taught---as part of nate or even licensing because customers are charged for all this craziness. Great video.
I have been thinking wrong how the capacitor works! Thanks for this video.
ONE OF THE BEST VIDEO ON HVAC THAT I HAVE SEEN (I'm a retired Engineer)
Capacitors increasing voltage: A person can easily get this conclusion if they measure the A.C. voltage on the input to a rectifier with a capacitor across the output of the rectifier without a load. In North America the A.C. line voltage will measure using a DVM at something near 120 volts A.C. while the D.C. side will read the highest voltage reached during the A.C. cycle which will be 169.7 volts D.C.
The idea of A.C. RMS voltage is the same number as an equivalent continues D.C. voltage that would provide the same electric Power to a purely resistant D.C. load. A purely resistant heating element would be expected to produce the same heat from 120 volts A.C. or 120 smooth D.C. Really liked your lecture! Good engagement with the students!
I had a 3750 sqft home (Chicago suburb) with 2 furnaces and 2 central air units. The Rheem condensers were 3 ton & 2 1/2 ton. Walking past the condensers I noticed one of the units was hummimg but not running. I took a rubber hammer and tapped the side of the case and the unit started running (I did this twice in 2 weeks). The units were 10 years old ( I bought the home new and these were installed new). Having a lot of experiences with oil filled motors, I knew there might be a bearing wear issue and when the unit stopped in the wrong place it would not start. I installed a hard start kit that I got with a bunch of electrical parts from a friend. Four years later I sold my home and it was still working, units were 14 years old. The furnaces were Bryant 90 plus and one did need a repair in that same year, but it was only a relay and sensing element. No other problems in the 14 years on those units. Thanks….Jim
PS….my current new ranch home has a Trane 80 plus furnace (builder sub installed) and a York a/c system with condenser (a licensed friend & I installed) running 19 years without any problems or repairs.
At around 9:20 you mention that the start winding is “always in place” and that it is not disconnected. Just for your viewers, some single phase motors do disconnect the start winding via a centrifugal switch inside the motor or externally with an electronic Start Switch like a Stearns SINPAC. Great video! I didn’t know the compressor motor left the start windings in play.
It is a Start Cap not a run.
I found the video interesting and learned a lot on how the capacitor is used to commutate the motor in a single-phase system. The one word of caution is at the end of your video you talked about plugging the cap into the wall and pulling it out to see what voltage you would get. This is fine on a non-polarized cap like a starter cap, but you mentioned an electrolytic capacitor, which is polarized and will explode if you plug it into the wall voltage. Polarized means it is mean for a DC voltage and will have a "+" symbol for the positive terminal. I' one of those electrical engineers you mentioned:)
Stop blathering and get your own channel.
False;
Go back and review; he mentioned electrolytic START capacitors, which by definition, are non-polar...
Hopefully, someone viewing this video knows the difference. Yes, you are absolutely correct to warn anyone NOT to try this with a POLARIZED (DC) capacitor...
Most start capacitors over 100µF are non-polar electrolytics (rated only for intermittent duty [they heat up rapidly from the IR losses])
Mr K L (technician and engineering background).
I would love to see a follow up to this adding in potential relays and current relays . This was a great way to hear this and made sense for me. Thanks hvac school
yes, good point!
Better managing the cap is the smart way to go.
Keeping the start cap in circuit is source of heat and troubles.
Hello Bryan, Great class. I went to a two year HVAC coarse years ago. It took a long time to figure out capacitors. You did a great job explaining this. I do happen to agree with Nova Air about current leading the voltage.
Taking a free prenn foster course in HVACR. Your videos have taught me way more by far. Mahalo from Hawaii
I like the analogy of the ballon or the bladder tank a pump, I think it is one of the best analogies to clarify how a capacitor works in the circuit
Great job Bryan as usual! and you got really nice interactive techs over there
really funny to see Bryan's excitement @26:00 when he talks about hooking up a capacitor to your outlet
These balloons can develop negative pressure so a bladder restriction would represent it best. Electrons don't pass through them just as water or air wouldn't pass through the bladder, but can affect the other side in similar fashion.
And if subjected to too high a pressure (or voltage in the case of the capacitor), thar she blows 😉
Or a plumbing expansion tank. With a backflow preventer and regulator, the supply will only provide 60psi (for example). In a closed system with all faucets closed after just running hot water, the water heater will fire and increase the psi from heating the cool water that entered the water heater tank while the hot faucet was on. The expansion tank is normally pressurized to 60psi, but the expanding water pressure will push the diaphragm allowing water to flow into the tank (let's say gradually increasing pressure to 65psi instead of 90psi without a tank). This extra pressure is then released when a faucet is opened and the system returns to 60psi when the faucet is closed. However the role of capacitor for a compressor and role of expansion tank in plumbing are totally unrelated.
BAD IDEA!
I contributed to New Age Neon, the standard handbook for Neon sign workshops. Managed the biggest Neon sign factory in the southern hemisphere and contributed to the understanding of Sprites and associated unusual lightening phenomena. I never came across anyone who valued the Right Hand Rule: Force, field, flow. We caused beer signs to illuminate without electrical contact, only field. The lack of electrical engineers understanding of field caused regulations enacted that caused millions list to fires and deaths too. It is important even at ten amps at 60 Hertz. We were handling 10,000hz. And 18,000 V at three amps. We used radio waves in testing too.
From charGPT,
In the start sequence of an AC compressor, a capacitor is used to improve the compressor's starting performance. Specifically, a start capacitor provides a temporary boost of electrical energy to help the compressor motor start more easily. Here's how it works:
1. Starting Torque: The capacitor creates a phase shift in the current, which improves the starting torque of the motor. This helps the motor overcome initial inertia and get up to operating speed more efficiently.
2. Smooth Operation: After the compressor starts, the capacitor usually disconnects from the circuit (in the case of a start capacitor) or remains in the circuit to improve efficiency (in the case of a run capacitor). This helps ensure smooth and efficient operation.
Great video and explanation. A capacitor in this application acts much the same as an accumulator in hydraulics, or a pressure tank in plumbing. All of these items can release a lot of energy(pressure/volume) fast, when needed. Cheers.
I learn something new everytime I hear someone else give their explanation and this video was very good. Great analogy
You guys are awesome! I just started teaching HVACR at a community college in North Carolina, and I share lots of your content because it's well-explained and you have some hilarious moments as do we! Keep up the good work.
I loved this video, I learnt so much, as an older technician I’m always learning.
I use hard start capacitor kits to replace the current relay and start capacitor with great success I have seen them last 12years then fitted another and away it goes again. I almost never use the original start components and have kept many compressor running for many years , I have been using them for about 15years now. I never get caught without starting components. You can’t save them all but most you can.
So wrong...
@@davidknightaudio934 that is your opinion but I have proven this works over 15years, I think you should always have an open mind, just because it has always been done a certain way doesn’t make it the only way or the best, always strive to do better. All the best
Bryan ..I have always thought of a 3 phase motor as a 3 cylinder engine...each phase firing 120 degrees out phase. If that helps ..?? Very well explained for everything else, SIR!
Awesome analogy, I'm a well guy,you just turned on a light for my capacitor understanding.Thank you.
Excellent definition of what caps do and how they do it. Like he says, its not magic and its not terribly hard to understand and you dont have to go 6 layers deep to get the gist of a caps function.
Fantastic video!! The presentation was clear and informative. If I ever decide to become a HVAC tech, I would want this guy for an instructor. Would like to see a class on these soft start units that are advertised for RV a/c units to reduce demand for amps at compressor start up. Throwing it out there for a topic of discussion in case you wanted input. Thanks!
Your a great Teacher, clear, concise and easy to understand.....
This is your best explanation, I heard so far. Thank you so much for using the analogies, it made a world of difference for me. I finally comprehend it fully. The analogy you used was something I was familiar with the expansion tank for a water pump, I actually replaced the bladder on one tank, and had to fill the air surrounding it to 30 lbs to keep it from rubbing against the inside surface. So yeah made a lot of sense.
Excellent. I’m an HVAC instructor at FSCJ IN JACKSONVILLE Fl
So, a capacitor works by transferring energy via the electric field. Typically, it blocks DC and it takes AC to transfer the energy (again, through the electric field) from one side of the capacitor to the other. A capacitor also causes a phase shift in the applied energy, where the current in a capacitor begins to lead (or come before) the voltage in the circuit. Inevitably, you will find circuits where there is a large amount of inductance involved. (an inductor transfers energy by a magnetic [or electromagnetic]) field. This typically is found in motors, which exhibit the properties of an inductor. And in an inductive (typically, a motor) circuit, it exhibits the opposite properties of a capacitive circuit; that is, in an inductive circuit you will find that the Voltage in a circuit begins to lead (or come before) the current in a circuit. Now, it is important to realize three things, 1) that if you have an inductor (typically, a motor) in the circuit, and a capacitor in the circuit, that essentially, to the extent possible, (depending the amount of capacitive reactance, and the amount of inductive reactance in the circuit) they will tend to cancel each other out; and 2) the most actual power transfer takes place when the current is 100% in phase with the voltage; and 3) that happens when the capacitive reactance of the capacitor cancels out the inductive reactance of the motor. And then, there is no resulting phase shift. Consequently we hit that golden point where as much power as possible is being transferred from the source (in an AC, usually 240 VAC) to the load (usually an Air Conditioner or fan motor). Other higher voltages can be used where more power is needed to be used, but while higher voltages are common in industry, they are not so common in home use. Above, I mentioned Capacitive Reactance (typically called Xc ... [usually pronounced "X sub C"]), and Inductive Reactance (typically called Xl ... [usually pronounced "X sub L"]). There a formulas for both of these, and deeper explanations for both of these all over the internet. But when Xc = Xl ... there is no phase shift, and you have maximum power transfer from the source to the load. One additional point. In the starting of a motor, the amount of Xc needed to cancel out Xl is greater, and all the time changing during the 'speed up' phase, until the motor reaches full speed, where Xl levels out. That is why there are two different values of capacitors used, 1) for the "start" circuit, and 2) for the "run" circuit. Xc for the 'Start' circuit is typically optimized for the startup phase, and Xl is typically pretty close to where it needs to be for the "run" phase, thereby providing the most efficient of both worlds ... start phase and run phase. These are basic electrical as well as electronic principles. Sadly, many never grasp the meaning, and come to an understanding of why. And I have to admit, it took me a long time to come to that realization. But when the 'Ah Ha' comes ... you will be forever improved at your particular tasks, whether electrically or or electronically. And, especially, in a motor circuit, you will understand what the actual purpose of that 'start' - 'run' capacitor actually is.
All of that is true, however You’re not making the difference clear between a capacitor that corrects power factor with a start capacitor. Start capacitors in a motor are only used for the phase shift on the start winding. Their purpose is not to reduce the VARs of the circuit or increase power factor. Which is what he explains in the video. In fact if the run windings are at 100% power factor, the start capacitor will increase the VARs for the start winding because that is what causes the phase shift and what is necessary to get the motor spinning
@@benheaton3728 You are correct. I didn't mention power factor, in the sense that I didn't name it. But it does have to do with that phase shift in the circuit. That phase shift occurs when the capacitive reactance isn't quite balancing the phase shift in the other direction due to inductive reactance. In that case, magnitude of Xl does not equal the magnitude of Xc, and there is a resulting phase shift (because it is not completely cancelled). The power factor is a single mathematical description of that resulting phase shift where PF = COS(Theta), which says that Power factor is equal to the cosine of the resulting phase angle. If I remember my theory correctly, when PF = 1, it is in phase, and the most energy is transferred from the source to the load.
Well, they're used all the time in pure DC circuits, so they do work in DC.
There is never energy transferred directly from one side to the other. When voltage is applied to one side the opposite polarity induces voltage on the other side of the capacitor. So imagine a positive voltage applied to side 1. As the voltage ramps up in the run coil and the magnetic field is induced, side 2 of the capacitor charges through the voltage force pulling or pushing on the start coil, creating a second magnetic field.
Best scam to make money, we need heavy duty capacity
Great class thank you for posting. Richard from Las Vegas here.
Bryan you are an excellent instructor. Fascinating learning from you. Thank you.
Great explanation. Easy to understand. You're a good teacher.
Great video - truly my new favorite YT channel. Quick question - if you replace a compressor on a unit that has a HSK, why would you keep the HSK in the system? Isn't the HSK only installed due to the compressor being on its last legs so when replaced, the HSK would no longer be necessary?
Love this. Having to work on my AC. Knew I needed to learn more to do it right, cuz I only had generalized ideas of how it all worked.
Fantastic explanation and all the metaphors were spot on!!!! Thank you for sharing this knowledge and approach to learning how HVAC systems work! Great job Bryan!!!
Can't complain -- it's a fairly good video. I sort of like how they embrace what they 'think' or 'visualize' is happening over what's actually happening. Myself, I have a good electrical engineering background, but know nothing of HVAC units... When he discusses the wheel of fortune wheel and the 'third hand,' I chuckle because it gets the idea across, but I think it's missing a key component.
1) Most people know that magnetics either attract or repel, depending on the poles.
This is the fundamental working force behind a motor, you construct a system such that the repelling / attracting force of two magnets make it spin.
2) Most people also know you can make a magnet by passing current through a wire.
3) Lastly, most people know the 'pole' of an electro magnet (one made by passing current through a wire) is determined by the direction of the current (i.e. the polarity of the source voltage)
What's missing I think for some people, like myself, is the revelation that HVAC motors do not have static / permanent magnets. They instead use electromagnets for both the stationary and spinning sides of the motor. How is one expected to control the poles of the magnets such that it spins, if both sides are powered by a single phase power source? That'd make both sides N at the same time, and both sides S at the same time, locking the motor in place. The answer is the capacitor; a phase shift that makes one side N, the other S with just the right timing to get it moving. Once moving, the alternating periodicity of the power source keeps it moving.
Very helpful information. It’s true, the electronic theory it’s not really necessary to understand what the compressor is doing in terms of the service man. I guess they don’t use the old fashion potential relays anymore. They are designed to take the starter capacitor out of a circuit mechanically.
Just like so many of your videos this one gave me good insights in terms of troubleshooting what has happened in the compressor. There’s also a slight difference between a label and the actual value of the capacitor.
I liked your explanation about the percentage of difference from the total, when choosing, whether or not to use another capacitor that is close in value.
Damn, this guy is effing awesome. He explains in a thorough and clear way.
Nicely done! I will be sending this to our apprentices, great explanation.
Send it me too. Lol
@@jasonjohnsonHVAC did you not just watch it?
For ac that is actually not the right symbol for a capacitor as the one you show is polarized so only for DC.
The symbol for an un polarized cap is just 2 straight lines instead ( two T instead of one curved)
It is semi common for non polarized caps to have a curved line. While I hate when part of the world use them, its the + next to one of the lines that makes it polarized.
I was going to say the same thing, you are 100% correct, we are talking about 220VAC unrectified voltage here, the symbol with a curve shows polarity i.e. the negative most side. You CAN'T (or at least not supposed to) use this symbol because there is no ground reference (or lowest FIXED negative value i.e. -110VDC). You can't even argue that the wave swings to -110VAC, because in the next half cycle it is now +110VAC and the capacitor would be considered reverse bias polarity for that half wave (and boom goes the dynamite after a few cycles of 50 amps of the dielectric boiling to the explosion point). There is a reason why there are two capacitor drawing types for both polarized and non-polarized capacitors. My skin crawled when he said just stick it in a wall outlet as the example. If that was done with a polarized cap, you now have a deadly firework in your hands when it overheats and explodes from the reverse polarity 1/2 wave cycles. If the cap is non-polarized, as these HVAC caps are, then yes, his stick in it the wall and measure under controlled conditions can be checked and validated as he says. Overall, the presentation is excellent and well thought out, it's just a minor thing regarding the symbol usage of the capacitor that should be tweaked to ensure proper proliferation of the component identification. To anyone saying "the rest of the world"... that is a lovely sentiment, pick up an accredited EE book and then find the section on capacitor identification between the two types, your region may do it differently because... well whatever reason, honestly, no one cares why you're doing it wrong, but technically it is wrong, any EE book on the subject matter outlines these facts and if it is being regionally done another way, that is another topic entirely.
Good video
Capacitor used on AC doesn’t have polarity
Capacitors doesn’t reduce the amount of current, just de-phase the voltage and current (shift forward the current from the voltage)
AC voltage doesn’t goes from 0 to 150 as the video said, in facts it goods from -150 to +150
The capacitor also dictates how much current can get through by its size in micro Farads it fills up on half the wave and dumps on the other half what it has stored with is dictated by its size hence it does effectively limit current
Thank you for an interesting, informative, well-presented lesson on capacitors.
As an electrical engineer, I can assure you that a hard start kit does not reduce start current. It actually increases current a minor amount, but it reduces the spin up time by increasing initial spin up torque of single phase induction motor. By reducing the start time, the high surge current period is shortened.
The only legitimate use of a hard start kit is for low AC voltage at compressor either due to low grid voltage or too much wire voltage drop from circuit breaker panel due to long wire run and/or too small wire gauge used to compressor during the high startup surge current. The lower the voltage applied to compressor the longer the motor spin up time and the startup surge current time length.
The run capacitor value is selected to provide 90 degrees of current phase shift to the start (auxiliary) winding of motor only for run condition. This provides better motor torque for given AC current while running and also improves the motor running power factor. The run capacitor value is not optimized for motor startup. It is optimized for run state of motor.
During startup the motor is highly inductive. To provide 90 degs optimum current phase shift to start winding during startup for maximum torque, the start capacitor would need to be three to four times the run capacitor value. Once the motor spins up, the motor is less inductive and the value of optimum capacitor to start winding must be changed to lower value to provide 90 degrees current shift during run state.
Hardstart kits do this with a relay that opens start capacitor connection when back EMF from start winding rises after motor spins up. You will typically see 290 to 300 vac from compressor common to start winding terminal after startup on a 240vac system.
If you put your amp meter on compressor common wire and measure compressor current, then put amp meter on compressor run wire and measure it, then start winding of compressor and measure its current. the sum of run wire current and start winding current will be greater than compressor common wire current. How can that be? It is because the start winding current through the run capacitor is shifted in phase by about 90 degrees during motor run condition.
For example, common current is about 12A, run wire current is about 10 amps, start winding current is about 7 amps. The result is because 10A run at 0 degs phase reference plus 7 amps at 90 degrees current offset equals 12-amp sum when done with vector phasing addition.
Three phase motors have three windings, offset by 120 degrees physically with corresponding 3 phase AC drive. This creates a rotating magnetic field necessary to get motor spinning. Single phase motor has to synthesize another AC phase source to create a rotating field to get motor to spin up. This is done by starter (auxilary) winding which is physically wound 90 degrees offset from run winding and the series capacitor to synthesize the second AC source phase with 90 degrees offset from single phase AC input.
In reading a book about Ben Franklin when he was messing around with electricy he found that he could collect it with different materials in a glass jar. Then figured out that connecting them depending on whether in series or parallel he could increase the amperage or voltage, he call the collection a battery. Sounds more like a capacitor.
It was long before Franklin. It's called a Leyden Jar. Dummy. Do you people never read books anymore? See Pieter van Musschenbroek of Leiden, 1745.
@@foobarmaximus3506 so sorry to offend a A worldly scholar such as you.
Blown capacitors might have a "bump" on top, where the relief valve is located.
Side-note: Stand-up refrigerators compressors don't have the "start" winding always connected, only at start time.
wrong
@@foobarmaximus3506 No, Freedom Speech is correct;
Most domestic refrigerators/freezers with fractional HP hermetics have start 'relays' or PTCs that effectively cut current to the start winding after the start cycle...
Mr K L
We have a 14 year old Goodman Heatpump here in N. Floo’da, runs fine, 1.5 years ago a AmRad Turbo200 was put on it when the stock Cap went bad, Now we have a 5-2-1 HS Kit on it, but the Turbo200 has the Orange 🍊 CPT post on it to protect the compressor from getting power if the cap failed, you just put the wire from the HSK to the Orange CPT post instead of the Common post of the main capacitor…!! 22:15. Do you agree?? BTW, You’re a Great Teacher. ✅
Interesting. Now understand how a hard start works. Thanks for the info.
ELI the ICE man
In an inductive circuit, voltage leads current by 90*
In a capacitive circuit, current leads voltage by 90*
The PSC motor is a capacitive inductive circuit
The capacitor is trying to neutralize the phase shift in the start winding, that was originally caused by the run winding being shifted by the inductive circuit.
The effect is that there are more “north and south” poles making the motor more efficient and more powerful by having electromagnetic forces applied at multiple points at any given time.
Excellent info---and all for the the cost of internet.----thanks.
This has been one of your better videos that I liked maybe cause I got more out of it thanks again.
One of the points that is missed here is low supply voltage during the short LRA that occurs on start up. This is real common, and should be one of the first things to check. I’ve seen electricians run too small of conductors, which causes low voltage on compressor start up. This can also be caused by high resistance connections at the sub panel, the disconnect, the contactor, etc. I have seen this numerous times. The spec is that the voltage should be within 10% the rated voltage, on start up, or what is specified on the unit nameplate. Measuring static supply voltage wii not catch this. Just like checking for power, as the first step of trouble shooting, voltage drop on compressor start up needs to be checked as one of the first tests. Think of a garden hose with 60 lbs of pressure, when it is not flowing, then when the valve is opened, there is low flow, and low pressure at the end of the hose, because the hose is too small. I am surprised this important concept was not covered as a cause of failure of a compressor to start..
Please explain the back EMF and the reason why capacitors have such high voltage ratings compared to the actual line voltage. I don’t think hardly anybody realizes why the voltage rating is so high on a capacitor but it is a result of the induction of the collapsing field
The magnetic field an inductor creates doesn't like current changes. As the current supply to an inductive load goes away the voltage will raise to try and keep the current the same. While this transient spike is easy to contain, the voltage and current get out of phase. A capacitor changes the phase in the opposite direction. You use the two together to align the current and voltage phases to create resonance, and remove standing waves. A simple LC circuit. Remember, you are working with waves. Inductance not only has a resistive element, but also the inductive and campacitive components. The values of each are a function of the primary frequency. This probolly sounds like Chinese, and you will need to learn the math to fully understand it.
@@falsedragon33 AFAIK, run caps are nowhere near resonance. If they were, I think the voltage would rise (resonate) off the charts... [I'd have to calculate the Q, and then there back EMF, which changes it from a simple RCL equation...]
You asked for the symbol of a capacitor. There are several symbols used. I'm not going to try to show them here, some show which side of the capacitor is the outside of the wound foil, for our purposes, it doesn't matter. There are a few symbols to show an electrolytic capacitor, where the polarity is shown. Electrolytics are polar-sensitive, you connect them backwards, they blow up in your face, that's to DC. Often internally, AC capacitors are non-polar, internally they could be two electrolytics in series, back to back, which makes polar devices into non-polar, and as said, sever different symbols are used. Then there are other types that are variable, some are called varicaps, the capacitance is adjusted by the applied voltage, but not in the HVAC business. I could go on and on. What confuses some people are the symbols used for switches, some put them into two categories, electronic and industrial. Having worked both sides, not confusing at all to me, but if one has only worked in industrial electronics, may not make sense.
Just to make the water more muddy.
Jim
Really excellent explanation in plain English! And funny, too. Many thanks!
The start winding dosnt get its power from the run winding it does come from the cap it just dosnt pass straight thru the cap the cap charges then on the next cycle dumps its stored charge into the start winding its capacity dictates how much power it dumps into the start winding and the charging and discharging happening at two different times on the sine wave is how it creates a phase change also having a potential relay stick closed can taost the winding but it can also cause the cap to explode other than that you're spot on with everything I'm really glad to finally see someone who knows what they're talking about doing one of these videos so many people who just come up with their own theory make videos and they are wrong
And when I say it's capacity I mean the micro Farad rating of the cap not the voltage
Very well said still don’t know what a capacitor does lol but it gave me a idea of what is trying to do i’ve been doing this for 40 years and that was the best explanation I’ve heard 👍
the mystery of the electron
Thanks as always your content is solid.
I know for me the most recent key to understanding how electricity works is how it is created from electro magnetic fields which pushes and pulls the electrons through the circuit and then in the case of inductive load it been creates electro magnetic fields
Maybe I missed it but I would love to hear your take on how electricity flows in each circuit from the power plant transmission lines and the service seeds of a building our home. And then last but not least how electricity is consume if you will.
I love listening to you. Your explanations are quite good. HOWEVER, don't use "attractive" force when talking about capacitors, electrons going in one side of the capacitor repel electrons (across that plastic film) and push them out the other side. The balloon analogy is good, but use two balloons sharing a fixed container. When you push air in one balloon, it squeezes air out of the other. As one balloon fills up, it becomes harder to continue to push air in that side (acts like a variable, increasing resistor). You get all that pressure back when you switch to the other half of the cycle. During the cycle, as the voltage approaches zero, one balloon is as full as it can get, creating back-pressure (high resistance to current). When the cycle passes through zero, that pressure (voltage) is released creating high current. NOTE: you get decreasing current while the line voltage is increasing and you get high current when line voltage passes through zero! This is the cause of the phase shift observed with capacitors.
Thank you for this excellent presentation!
I like the 'third hand' analogy.
I am surprised at how little these students know about electricity in this class.
You should see how little they know when they ask me for a job. Most trade schools do a horrible job prepping these kids for the real world.
TFJD: Im surprised you would make this statement knowing nothing about where they are, either in the unit or curriculum. This could be Day 3 for a bunch of kids coming in green off the streets.
I kinda understood but your explanation was pretty good. I appreciate the information. I definitely feel more confident in my knowledge.
Great video. I installed a 5-2-1 start kit on my 4 ton unit. It is properly sized (3.5 to 5 ton) for the unit. You have me a little worried about not using the factory kit. Unit is 20 yrs old and has been running great. Should I be worried?
Not at all. The 5-2-1 brand is the best "fits all" start kit. Trane is the only brand that has specific separate part numbers for the relays and start capacitors, you buy them separately as opposed to the 5-2-1 being preassembled. The engineers at 5-2-1 claim their relays open sooner than other brands thus reducing the risk of overload on the S circuit.
@@briangc1972 - thank you - my Carrier/Copeland compressor has the start capacitor sized for the 1-3 ton 5-2-1 product (CSR-U1) even though it is a 4 ton unit and 5-2-1 recommends the CSR-U2 product. I went ahead and went with the same capacitor that Copeland specs - the CSR-U1 and not the CSR-U2. So I am running as close to the OEM part that is possible it is just that 5-2-1 made it. The start amp drop is a little more signifigant using the CSR-U2 which went from 108amps to 58 amps (I installed the CSR-U2 before looking into the OEM part and realizing I really needed the CSR-U1). The CSR-U1 start up amps went from 108 to 76 amps So not as good as CSR-U2 but not sure what else needs to be considered. Thanks again Brian
@@condor5635 I would install the CSR-U2
I found when I have used the U1 on 3.5 or 4 ton compressors that they do not last as long.
@@briangc1972 - thanks for the advice. It’s just disconcerting knowing that that’s not what the OEM part is. I don’t know what the technical details are - pros and cons of using the larger capacitor. Could it be damaging the compressor more than the other one even though it seems to work fine?
Glad I came across this video. I have my home set up with a generator disconnect and want to run my ac with the generator. But my generator doesn't push enough power to start the AC unit. I have been told that a hard start will allow this. But the AC runs fine now. So my question is this. Is there any harm with installing a hard start kit on a AC unit that is running fine, so when the power goes out and I am operating off generator power the hard start is already in place and ready to go? Also what are your thoughts on a micro air soft start kit?
Another great video, always look forward to learning. Thanks Brian!
Great video! I have no formal education on A/C and I have not been able to get a good understanding of capacitors from my licensed A/C technicians. I am installing a 10k 30amp generator and would like to know if a soft start is any better than a hard start. I was looking at a soft start from Micro Air which is almost $400 and I'm wondering if it is better for the unit than a hard start. Any comments is appreciated. Thx
I'm old school taught. The theory of split phase is , to me, the function of the capacitor, and is what generates stronger magnetic fields temporarily, to increase the ability of the physical motion of an inductive motor, without overall increase of wattage uselessly expended by the motor. In fact it decreases it.
In any electric sine wave there are two components, current, and voltage. The motor typically starts on the current wave, and runs on the voltage wave. In a capacitive circuit the current wave is split away from and precedes the voltage wave. As the current wave reaches its peak the voltage wave is at or near zero. As the voltage wave approaches it's delayed peak, current in the capacitor approaches zero. I wish I could draw the 2 waves as they pass through a capacitive circuit for you, and compare it to the single phase inductive motor sine wave, but you can likely find this in a different video that does focus on 'capacitor start, capacitor run inductive motor'.
It has been my experience that a properly applied start capacitor along with the correct (very important ) run capacitor, given the motor windings are close enough in relative resistance , thus designed to implement a run cap. during operation, actually can enhance the performance and increases the lifespan of an inductive motor.
With a solid state start relay, you can actually hear the motor kick on to full speed considerably quicker after a start cap. is installed. Same with a mechanical start relay, but it is less pronounced, even though it does much the same thing. The less time you can spend with the start windings getting full current, the longer the motor will last, generally speaking. The start windings seem to be the weakest link in an inductive motor, over time, as they have far higher dynamic power fluctuation when you consider the watts per inch load required to start the motor in day to day operation. Getting those start amps down to run amps as quickly as possible is not only efficient, it is also less stress on the motor windings, as they are subject to expansion and contraction directly proportional to current induced heating and cooling.
I would recommend studying split phase analysis and implementation if you decide you want to understand electrical theory in that respect. And I would encourage an understanding of inductive resistance as well.
The field of electrical theory can be understood if properly taught, and will be extremely helpful in these hvacr jobs in your distant future. Of course each teacher has their own style and way of understanding this field and what they consider important enough to convey it understandably to the students. I feel very fortunate to have had Richard Deputy as my instructor on this subject in 1986. A very smart man, and a very good instructor. Would that I could be more like him.👍
I learn something knew as often as possible. It's a good feeling when I do, as this is my lifelong trade. And I hope I learn from my mistakes, and try to
pay close attention to them. I will not ever know everything. 👍
Most A/C units will require 12kw surge to start with a 5-2-1 start kit (licensed contractor here)
Great video. Thank you for all the information. Cheers!
Sir you are an excellent teacher!
I like to use mechanical and fluid analogue, where voltage is something like pressure. A resistor is a sponge or constriction. An inductor is a flywheel driven by a displacement pump acting as a motor. A capacitor is a double-acting piston with a centring spring whose spring constant is the inverse of the capacitance. A motor depends on having a rotating magnetic field. Three phases 120° apart in phase and 120° geometrically (in space) makes for a perfectly steadily rotating field. Single-phase makes for a useless linearly oscillating field, like stamping on bicycle pedals stuck at TDC and BDC. A single-phase motor makes an elliptical rotating field (strong in one axis, weak on the other) with the help of a wining that has an angle difference (phase shift) in space and electrically (i.e., in time) that works like pushing a foot forward on the bicycle pedal at TDC. The phase shift is important because if the start-run capacitor were replaced with a resistor or a lower voltage supply matching the original phase, the rotating magnetic field would degenerate into a useless linear oscillating field, just inclined at a fixed angle. In such a case, the motor's impedance appears as resistance rather than reactance (with a little resistance), so it turns into a heating element. (Reactance is what you get when you use a flywheel or a trampoline, resistance is what you get when you drive your hand through syrup, dissipating energy as heat.)
For some reason there were no (0) likes on this video, on my screen? Well i just left one like! It is super helpful to see your videos and I’m very thankful that you took the time to record and post the information in regards to capacitors. I’ve heard a lot of people try to explain what they are and nobody knew what they were talking about. LOL! So it’s great to see you actually know what it is!
Im in my 5th month of working in AC. All of this is like Greek to me. Glad others are getting this though. Will have to find a simpler video.
Well done!!!
This is the way to teach a class
Great job 😊
Umm, WHUT? 1:15 and before, you're drawing the symbol for a polarized capacitor while these are non-polarized with a symbol that is two straight lines in parallel, not one of them curved which is for a polarized capacitor. Some people might think that because there's a common that this makes it polarized but it does not, that is just a simplified construction method that shares one of the poles of two NP caps.
Yes!!! He was confusing me with that technically but I get where he was going with it
This really helped me understand cap. function. Thanks. BTW, I am not a sparky by nature. I avoid this art form at all costs. Yet, a bit of basics is handy sometimes.
You are a great instructor. Thank you!
Great info. Best explanation
Robert
Do you get higher voltages across the capacitor due to back emf ?? Have you a video explaining this.. I found this video great.
The opposite phase shift of the two parts causes the measured capacitor voltage and motor winding voltage to appear significantly larger than you would expect. Depending if the circuit is close to the resonant frequency (Xl = Xc) or not, and the Q (resistive loss) it is possible to have higher voltage on one or both component than the line voltage applied across the series combination. (I was an RF Transmitter tech back when tubes were popular so I got to play with big motors AND RF circuits).
Great explication of the capacitors functionality
Well explained thank you very much.
By connecting the phase line to the start coil and connecting the run capacitor in series with the running coil direction of rotation will be reversed.
Its long story why i have to but, One time i have fitted by reversing the direction of single phase fun motor and it run continously for about 1 month until i recieve another one.
I would like to know how bad is it the fun and what could have happen to it?
It is not designed for that.
The run winding and start windings have different resistances, and have different designed running amps going through them.
Wiring it backwards likely creates excessive heating in the wrong places.]Hopefully the overload would protect it from damage (unless allowed to repeatedly cycle/shutdown).
Likely it overheats the start winding with excessive amps.
It might be possible to find a generic fan blade in the 'other-handed' rotation for you existing incorrect motor... check an HVAC supply house.
@@troubleshooter1975Thank you so much i understand now what could have happend. To be clear sir i did that not for expermenting. i was on board ship no spare on board & provision store(fish room) evaporator fan just faild so temporarly i just fixed another fan but its direction needs to be reversed by any means the store has to be saved. Luckly it withstand until we get the original fan.
Are 5-2-1 hard start kits any good for a 10 year old 5 ton system?
The symbol you have drawn is a polarized capacitor. By the way there is considered a current "flowing" it is a construct known as DISPLACEMENT CURRENT. This was a consequence of Maxwell Equations. The model we use is i = C dV/dt this is why if V is a sine wave the current will be a cosine wave . 90 degree phase change. Actually electrical and magnetic circuits are grossly oversimplified by lumped circuits. To understand electric effect deeply we need to use Electric and Magnetic Field theory trouble is it is very hard to understand, Hence the notion of displacement current versus electrons flowing.
do you guys have videos on low temp chillers or just chillers in general?
Search chillers you will find some videos, I have seen a few 👍
One guy out of Texas does videos on chillers. Don't want to disrespect this great channel, look around, good info everywhere.
@27:48 "...heaven forbid they're an electrical engineer..."
As a EE PE, I'm both offended and guilty ;-) . But great practical explanation!