Zack, I'm a Chartered Electrical Engineer and Technical Director for my company providing HV designs up to 132kV in the UK. I also provide training. Can I just say that your video is excellent. I was going to produce my own you tube presentation on this for internal training but I think I will just refer people to yours. No wasted words, no BS, no patronising explanations. 10/10. well done. I'll look at your other videos.
@ZackHartle
28 күн бұрын
Thanks so much for watching!
@finn5685 Жыл бұрын
I had so many lightbulb moments watching this, you explained it better than anyone has
@lowellweeks14483 ай бұрын
I haven't had to do these calculation in over 25 years. WOW Brilliant breakdown. Everything just came flooding back. Kudos!
@TIGREinVOLO2 жыл бұрын
Ok... first of all... you are genius. The set up you arranged with "black" board in reverse is a brilliant idea. For many reasons. On top of this, your explanation is simple and clear! Thank you
@maxgiantbanana73443 ай бұрын
Mr Hartle, this video is truly the best explanation of one of the foundational principle of transformer…thank you so much for sharing it
@LifexLess Жыл бұрын
Great video! Love the explanations, drawings, and blackboard. Cheers.
@MUTHU_KRISHNAN_K10 ай бұрын
Wow, Thank you very much for this amazing explanation. Understood crystal clear 🙏
@douglaslloyd79172 ай бұрын
Such a satisfying and helpful video, thank you so much!
@Danilo111 Жыл бұрын
Amazing … thanks for the excellent explanation
@yilehuli3 жыл бұрын
This percentage impedance along with the transformer voltage determines if the maximum fault current could be handled properly by the breakers. The bigger the transformer, the lower the percentage impedance. Good video.
@ZackHartle
3 жыл бұрын
Absolutely. Thanks for watching!
@Impedancenetwork
3 жыл бұрын
That second sentence is wrong. The larger the transformer, in general, the larger the impedance. If you drive down the road and see a 50kva pole mounted transformer it probably has a %IZ of 2.3-3% or close to that. If you see a 100MVA transformer it might be 6,7 or 8% IZ. In general the larger the transformer the larger the percent impedance.
@iosefoyagomate5647
3 жыл бұрын
Zack is correct..... just checked the nameplate of a single-phase 15kVA 7620/13200V 60HZ transformer which had a 1.9% IZ
@iosefoyagomate56473 жыл бұрын
Thank you Zack.
@electricterms Жыл бұрын
clear explanation thank you.
@aaronsmith6361 Жыл бұрын
Awesome video!
@abdelmalek96825 ай бұрын
You're a hell of a teacher love you maan
@SuperThanhphuong3 жыл бұрын
Great video ! Thanks
@ZackHartle
2 жыл бұрын
You are welcome!
@angelofranklin110 ай бұрын
Great vid thank you
@sambathbunkh8 ай бұрын
Best explanation for me.
@gamelover25942 жыл бұрын
that was very, very interesting :)
@nbkk7712 жыл бұрын
Extraordinary
@tejusshakti11279 ай бұрын
Superb.
@user-wm9vb1oe8o2 ай бұрын
Thank you sir
@amerdouleh28922 жыл бұрын
Great explanation
@ZackHartle
2 жыл бұрын
Glad it was helpful!
@manojillangasooriya35902 жыл бұрын
love it
@Jnglfvr2 жыл бұрын
It appears that the short circuit current can simply be calculated by realizing that if the current on the secondary is 37.5 A with 20 V on the primary then the current is (600/20)*37.5 = 1125 A when we have 600 V on the primary. (Ohms law). Your result was slightly different because of rounding error %IZ.
@glenneric18 ай бұрын
The whole concept of using 'ratings' to calculate actual values is what is throwing me off. I'm normally not this dumb. 😆
@deusexmachina34962 жыл бұрын
I'll just leave it there: the amount of voltage required to overcome the impedance of the transformer to reach max secondary current (i.e., secondary short-curcuit current, which is determined by the design)
@brendonshewchuk33102 жыл бұрын
Thanks! Just got me an extra mark on my 3 phase exam!
@ZackHartle
2 жыл бұрын
Excellent!
@alvaropires6497 Жыл бұрын
Thanks
@ZackHartle
Жыл бұрын
Thank you!
@turdfurguson7964Ай бұрын
Could you explain where you got 20 volts. Seems like you just picked a random voltage? Did I miss something?
@dwenraja145310 ай бұрын
im sorry but does this means that at 1136.4 amps the transformer will trip?
@wokeclub18443 жыл бұрын
Loved it.. Great explanation Could you please let me know the logic behind the formulae you've used .. For e.g: why should the short circuit current be equal to the rated secondary current divided by the percentage impedance? Many thanks .. subscribed!
@ZackHartle
3 жыл бұрын
So typically we say that short circuit has to do with available kVA and the voltage of the transformer, which using Rated current takes in to account both of those. The other thing to consider would be impedance of the short circuit path, that's why this video we are just talking about what's available in theory at the transformer, not what you would see actually at the short circuit point.
@jaymoseley6216
Жыл бұрын
If you change the percent impedance into actual impedance, your calculation for short circuit is just Vs/Z = Isc or a circuit with only your voltage source and your transformer impedance in series. All primary impedances are transferred over to the secondary side as one z equivalent. To get to z from %z you do the following. (1) Isc = Vs/Z (2) Z= %Z*Zbase where (3) Zbase = V^2/S Plugging (3) into (2) and (2) into (1) Isc = V/(%Z*V^2/S) = S*V/(%Z*V^2) = S/(%Z*V) Where S= V*A so Isc = V*A/(%Z*V) = A/%Z It is just ohms law with a lot of convenient variables that cancel out. The calcs with the actual transformer impedance for this example are shown below which results in the same answer. Zbase = (240V)^2/9000VA = 6.4 ohms Z = Zbase*Z% = 6.4ohm*.03333 = .21333 ohms Isc = Vs/Z = 240 V/2.1333 ohms = 1125A For the 3 phase case - Say three of these transformers were hooked up in a Delta-Y, Vllpri=Vphasepri = 600, Vphasesec = 240V and Vllsec=416V, then the equivalent transformer would be a 27kVA 3 phase 600-416/240 transformer with %Z of 3.333%. Your results would still be 1125A for the max available fault current per phase Isc = 27000/(3*240)*30 = 1125A
@ppellacani
Жыл бұрын
@@jaymoseley6216 this is what i was looking for when i came here. THANK YOU SIR!!!
@expnnt_designteam9609 Жыл бұрын
How do you consider %Z of a bank of three single phase transformer for 3 phase use ?
@brimmed
Жыл бұрын
Did you figure out the answer to that? I have my PE exam tomorrow fml
@johnfederspiel59752 жыл бұрын
Hi Zack, is this short circuit current only seen on the secondary? Could I reflect it to the primary?
@ZackHartle
2 жыл бұрын
It is the available fault current on the Secondary of the transformer. It's the maximum it can supply
@ww-mc8pv
2 жыл бұрын
@@ZackHartle Hello Zack, Could I reflect the fault current on the secondary to the primary?
@user-nk4sx3sq4u Жыл бұрын
Hello you mentioned in this video you can calculate losses of the transformer with the % impedance. How do you do that?
@ZackHartle
10 ай бұрын
I have a video on it. Closed circuit test
@bettercallmepol34932 жыл бұрын
It probably is a silly question but since we short circuited the secondary does the voltage remanis at 240V? Is it a constant voltage source the secondaryy????
@ZackHartle
2 жыл бұрын
Yes
@TFeld-nx9io5 ай бұрын
Are any factors, such as sqrt(3), needed if you have a 3 phase transformer?
@jeanhellsten
4 ай бұрын
I am trying to find out that too!
@angelofranklin110 ай бұрын
can you give an example of a three phase tx
@ZackHartle
9 ай бұрын
For percent impedance? A three-phase transformer is just 3 single phase transformers wired together in Wye or Delta
@malaivasan49722 жыл бұрын
Sir , how we can calculate drop voltage at primary with calculation. As mentioned u 20V how it s came? Without meter any possible for find that drop voltage
@ZackHartle
2 жыл бұрын
You would need a meter to measure it
@kris98112 жыл бұрын
i thought you need to divide by sqrt(3) to get secondary rated current
@ZackHartle
2 жыл бұрын
If it was a 3-phase transformer you would. This example is a single phase
@brimmed Жыл бұрын
where does the I_sc = I / %z formula come from?
@jaymoseley6216
Жыл бұрын
The percent impedance is what is called a per unit value. The base values for the system are implied to be the rating of the transformer, so the base kva is 9kva and the base voltage would be 240v. This is just a way to model systems to make it much much easier for power system and primarily fault analysis. A transformer just becomes it's equivalent impedance in series. The voltage due to the selected base (pu = actual/base) is now just 1 pu. So in a short circuit you have a simple series circuit with a voltage of 1pu and a reactance of .0333. Using ohms law 1pu/.0333 gives you a per unit short circuit current of 30 pu. To convert from pu back to actual fault current, you would just need to multiply the 30 pu by the base current which is determined by the given power and voltage bases. This also happens to be your secondary current, so - 9kva/240v = 37.5 and 30*37.5 = 1125A. Or to put it all together (base voltage in per unit)/(Transformer Impedance in pu)*Base Current = (1pu/.0333pu)*37.5A The voltage is not mentioned because it is selected to be 1pu, but it is in there. Its still just ohms law. Your not actually dividing by a impedance you're multiplying by a unitless current value. Current = (per unit current * base current) = 37.5/.03333 The equation is just a quick and easy way of combining those steps to determine the maximum available short circuit current at the secondary of any transformer. You'll more likely use it in this form Isc=S/(Root(3)*Vline*%z) or S/%z for your available fault duty if you are looking to incorporate other equipment for a quick rough calculation.
@jaymoseley6216
Жыл бұрын
I was explaining in the case where we know the impedance already, but testing for the impedance works the same. You adjust your voltage until you're at a known current to determine the impedance. So its the same simple series circuit with the same bases, but the tests adjust the voltage supply until the secondary is at rated current which is also its per unit base current so it equals 1pu, which eliminates an additional math step. This occurs at 20v or Vpu = 20/600=.03333 pu Using Ohms law Zpu = Vpu/Ipu = .0333pu/1pu.
@samanthalee11786 ай бұрын
How do I figure the 20 volts? How can it just be a guess?
@ZackHartle
5 ай бұрын
It is a measured value that you would read with a meter
@pitshoumbongo2 жыл бұрын
Is this how you do it for a 3phase transformer ?
@ZackHartle
2 жыл бұрын
You would do each of the 3 single-phase transformers separately.
@zpmayes Жыл бұрын
I have a transformer with %IZ and %IX, what is the difference?
@ZackHartle
Жыл бұрын
I'm not sure
@UmbrellaCorp_
7 ай бұрын
It's the percentage reactance of the transformer.... %X = (IX / V ) * 100
@eng.omareyadaljorani99542 жыл бұрын
Why we put a short circuit on secondary side of transformer to calculate percentage impedance? Why don't we put a load on secondary side in order to calculate the impedance?
@101slurpy2 жыл бұрын
are you writing backwards?
@ZackHartle
2 жыл бұрын
Ha ha, I am not, but I can't reveal all my secrets! It's just fancy camera tricks
@markmcgoveran68119 ай бұрын
When I was in electrical engineering school I met a guy that was an electrician and proud that he had learned all about electricity and it sure didn't take six or seven years to learn it. I said you know about a transformer it's made of copper wire and insulation, and iron. He said "I know what it's made out of". I said good now that you know what you need to use how much of each one do you put in?" He said "how the hell would you know that". I said"first you'd fall off a turnip truck in front of the University math department and stick around there for about 4 years convincing you was willing to pay the money and worthy of sitting in that seat. Then a guy who gets paid to tell people that would take a break and teach her class and you would have already proven you was worthy to try and understand what he was explaining because you understood what the math department was explaining and then a couple of years you could answer that question just like he can? Electrician scratched his head and left the bar.
@sethtaylor5938 Жыл бұрын
The short circuit current of the secondary of 1136 A is in theory true. However, In reality in an example where the source is 7200 volts to ground primary on a pole mounted distribution transformer and the impedance is 3.3% (with a 240 volt secondary) , that current will ALWAYS be limited to less than the calculated value as in this video. Most distribution transformers at First Energy were 3%. The 7200 (7.2KV) distribution source side case, that source may not be able to supply the current to achieve the theoretical value on the low voltage secondary. In the power utility business to do this calculation for the secondary fault current you have to know the short circuit AVAILABLE fault current of the SOURCE. Once you know that you can solve the problem. You can use CYME (tm) or if you know the available high side fault current (the electric company can tell you) then u can use the FREE EATON fault current I Phone AP to get the answer. The AP is available in the Apple(tm) Store or www.eaton.com/us/en-us/products/electrical-circuit-protection/fuses/fault-current-calculator.html. Once again, you need to know the available fault current of the source to get the answer. Why do u need to know this? Suppose there's a 25 KVA pole transformer, 7.2 KV primary, 120/240 secondary,100 feet of 1/0 TPX to the weather-head and 100 feet of #2 CU to the main breaker in the load center. The electrical inspector needs to know what is the available fault current at the panel. If it's under 10 KA, then u can use off the shelf breakers from the home center. If its over 10 KA but less than 22 KA, then you need more expensive breakers that can handle the predicted fault current. The electrician needs to know this too. When the primary is 19.9 KV phase to neutral, the available fault currents are always high.
Пікірлер: 74
Zack, I'm a Chartered Electrical Engineer and Technical Director for my company providing HV designs up to 132kV in the UK. I also provide training. Can I just say that your video is excellent. I was going to produce my own you tube presentation on this for internal training but I think I will just refer people to yours. No wasted words, no BS, no patronising explanations. 10/10. well done. I'll look at your other videos.
@ZackHartle
28 күн бұрын
Thanks so much for watching!
I had so many lightbulb moments watching this, you explained it better than anyone has
I haven't had to do these calculation in over 25 years. WOW Brilliant breakdown. Everything just came flooding back. Kudos!
Ok... first of all... you are genius. The set up you arranged with "black" board in reverse is a brilliant idea. For many reasons. On top of this, your explanation is simple and clear! Thank you
Mr Hartle, this video is truly the best explanation of one of the foundational principle of transformer…thank you so much for sharing it
Great video! Love the explanations, drawings, and blackboard. Cheers.
Wow, Thank you very much for this amazing explanation. Understood crystal clear 🙏
Such a satisfying and helpful video, thank you so much!
Amazing … thanks for the excellent explanation
This percentage impedance along with the transformer voltage determines if the maximum fault current could be handled properly by the breakers. The bigger the transformer, the lower the percentage impedance. Good video.
@ZackHartle
3 жыл бұрын
Absolutely. Thanks for watching!
@Impedancenetwork
3 жыл бұрын
That second sentence is wrong. The larger the transformer, in general, the larger the impedance. If you drive down the road and see a 50kva pole mounted transformer it probably has a %IZ of 2.3-3% or close to that. If you see a 100MVA transformer it might be 6,7 or 8% IZ. In general the larger the transformer the larger the percent impedance.
@iosefoyagomate5647
3 жыл бұрын
Zack is correct..... just checked the nameplate of a single-phase 15kVA 7620/13200V 60HZ transformer which had a 1.9% IZ
Thank you Zack.
clear explanation thank you.
Awesome video!
You're a hell of a teacher love you maan
Great video ! Thanks
@ZackHartle
2 жыл бұрын
You are welcome!
Great vid thank you
Best explanation for me.
that was very, very interesting :)
Extraordinary
Superb.
Thank you sir
Great explanation
@ZackHartle
2 жыл бұрын
Glad it was helpful!
love it
It appears that the short circuit current can simply be calculated by realizing that if the current on the secondary is 37.5 A with 20 V on the primary then the current is (600/20)*37.5 = 1125 A when we have 600 V on the primary. (Ohms law). Your result was slightly different because of rounding error %IZ.
The whole concept of using 'ratings' to calculate actual values is what is throwing me off. I'm normally not this dumb. 😆
I'll just leave it there: the amount of voltage required to overcome the impedance of the transformer to reach max secondary current (i.e., secondary short-curcuit current, which is determined by the design)
Thanks! Just got me an extra mark on my 3 phase exam!
@ZackHartle
2 жыл бұрын
Excellent!
Thanks
@ZackHartle
Жыл бұрын
Thank you!
Could you explain where you got 20 volts. Seems like you just picked a random voltage? Did I miss something?
im sorry but does this means that at 1136.4 amps the transformer will trip?
Loved it.. Great explanation Could you please let me know the logic behind the formulae you've used .. For e.g: why should the short circuit current be equal to the rated secondary current divided by the percentage impedance? Many thanks .. subscribed!
@ZackHartle
3 жыл бұрын
So typically we say that short circuit has to do with available kVA and the voltage of the transformer, which using Rated current takes in to account both of those. The other thing to consider would be impedance of the short circuit path, that's why this video we are just talking about what's available in theory at the transformer, not what you would see actually at the short circuit point.
@jaymoseley6216
Жыл бұрын
If you change the percent impedance into actual impedance, your calculation for short circuit is just Vs/Z = Isc or a circuit with only your voltage source and your transformer impedance in series. All primary impedances are transferred over to the secondary side as one z equivalent. To get to z from %z you do the following. (1) Isc = Vs/Z (2) Z= %Z*Zbase where (3) Zbase = V^2/S Plugging (3) into (2) and (2) into (1) Isc = V/(%Z*V^2/S) = S*V/(%Z*V^2) = S/(%Z*V) Where S= V*A so Isc = V*A/(%Z*V) = A/%Z It is just ohms law with a lot of convenient variables that cancel out. The calcs with the actual transformer impedance for this example are shown below which results in the same answer. Zbase = (240V)^2/9000VA = 6.4 ohms Z = Zbase*Z% = 6.4ohm*.03333 = .21333 ohms Isc = Vs/Z = 240 V/2.1333 ohms = 1125A For the 3 phase case - Say three of these transformers were hooked up in a Delta-Y, Vllpri=Vphasepri = 600, Vphasesec = 240V and Vllsec=416V, then the equivalent transformer would be a 27kVA 3 phase 600-416/240 transformer with %Z of 3.333%. Your results would still be 1125A for the max available fault current per phase Isc = 27000/(3*240)*30 = 1125A
@ppellacani
Жыл бұрын
@@jaymoseley6216 this is what i was looking for when i came here. THANK YOU SIR!!!
How do you consider %Z of a bank of three single phase transformer for 3 phase use ?
@brimmed
Жыл бұрын
Did you figure out the answer to that? I have my PE exam tomorrow fml
Hi Zack, is this short circuit current only seen on the secondary? Could I reflect it to the primary?
@ZackHartle
2 жыл бұрын
It is the available fault current on the Secondary of the transformer. It's the maximum it can supply
@ww-mc8pv
2 жыл бұрын
@@ZackHartle Hello Zack, Could I reflect the fault current on the secondary to the primary?
Hello you mentioned in this video you can calculate losses of the transformer with the % impedance. How do you do that?
@ZackHartle
10 ай бұрын
I have a video on it. Closed circuit test
It probably is a silly question but since we short circuited the secondary does the voltage remanis at 240V? Is it a constant voltage source the secondaryy????
@ZackHartle
2 жыл бұрын
Yes
Are any factors, such as sqrt(3), needed if you have a 3 phase transformer?
@jeanhellsten
4 ай бұрын
I am trying to find out that too!
can you give an example of a three phase tx
@ZackHartle
9 ай бұрын
For percent impedance? A three-phase transformer is just 3 single phase transformers wired together in Wye or Delta
Sir , how we can calculate drop voltage at primary with calculation. As mentioned u 20V how it s came? Without meter any possible for find that drop voltage
@ZackHartle
2 жыл бұрын
You would need a meter to measure it
i thought you need to divide by sqrt(3) to get secondary rated current
@ZackHartle
2 жыл бұрын
If it was a 3-phase transformer you would. This example is a single phase
where does the I_sc = I / %z formula come from?
@jaymoseley6216
Жыл бұрын
The percent impedance is what is called a per unit value. The base values for the system are implied to be the rating of the transformer, so the base kva is 9kva and the base voltage would be 240v. This is just a way to model systems to make it much much easier for power system and primarily fault analysis. A transformer just becomes it's equivalent impedance in series. The voltage due to the selected base (pu = actual/base) is now just 1 pu. So in a short circuit you have a simple series circuit with a voltage of 1pu and a reactance of .0333. Using ohms law 1pu/.0333 gives you a per unit short circuit current of 30 pu. To convert from pu back to actual fault current, you would just need to multiply the 30 pu by the base current which is determined by the given power and voltage bases. This also happens to be your secondary current, so - 9kva/240v = 37.5 and 30*37.5 = 1125A. Or to put it all together (base voltage in per unit)/(Transformer Impedance in pu)*Base Current = (1pu/.0333pu)*37.5A The voltage is not mentioned because it is selected to be 1pu, but it is in there. Its still just ohms law. Your not actually dividing by a impedance you're multiplying by a unitless current value. Current = (per unit current * base current) = 37.5/.03333 The equation is just a quick and easy way of combining those steps to determine the maximum available short circuit current at the secondary of any transformer. You'll more likely use it in this form Isc=S/(Root(3)*Vline*%z) or S/%z for your available fault duty if you are looking to incorporate other equipment for a quick rough calculation.
@jaymoseley6216
Жыл бұрын
I was explaining in the case where we know the impedance already, but testing for the impedance works the same. You adjust your voltage until you're at a known current to determine the impedance. So its the same simple series circuit with the same bases, but the tests adjust the voltage supply until the secondary is at rated current which is also its per unit base current so it equals 1pu, which eliminates an additional math step. This occurs at 20v or Vpu = 20/600=.03333 pu Using Ohms law Zpu = Vpu/Ipu = .0333pu/1pu.
How do I figure the 20 volts? How can it just be a guess?
@ZackHartle
5 ай бұрын
It is a measured value that you would read with a meter
Is this how you do it for a 3phase transformer ?
@ZackHartle
2 жыл бұрын
You would do each of the 3 single-phase transformers separately.
I have a transformer with %IZ and %IX, what is the difference?
@ZackHartle
Жыл бұрын
I'm not sure
@UmbrellaCorp_
7 ай бұрын
It's the percentage reactance of the transformer.... %X = (IX / V ) * 100
Why we put a short circuit on secondary side of transformer to calculate percentage impedance? Why don't we put a load on secondary side in order to calculate the impedance?
are you writing backwards?
@ZackHartle
2 жыл бұрын
Ha ha, I am not, but I can't reveal all my secrets! It's just fancy camera tricks
When I was in electrical engineering school I met a guy that was an electrician and proud that he had learned all about electricity and it sure didn't take six or seven years to learn it. I said you know about a transformer it's made of copper wire and insulation, and iron. He said "I know what it's made out of". I said good now that you know what you need to use how much of each one do you put in?" He said "how the hell would you know that". I said"first you'd fall off a turnip truck in front of the University math department and stick around there for about 4 years convincing you was willing to pay the money and worthy of sitting in that seat. Then a guy who gets paid to tell people that would take a break and teach her class and you would have already proven you was worthy to try and understand what he was explaining because you understood what the math department was explaining and then a couple of years you could answer that question just like he can? Electrician scratched his head and left the bar.
The short circuit current of the secondary of 1136 A is in theory true. However, In reality in an example where the source is 7200 volts to ground primary on a pole mounted distribution transformer and the impedance is 3.3% (with a 240 volt secondary) , that current will ALWAYS be limited to less than the calculated value as in this video. Most distribution transformers at First Energy were 3%. The 7200 (7.2KV) distribution source side case, that source may not be able to supply the current to achieve the theoretical value on the low voltage secondary. In the power utility business to do this calculation for the secondary fault current you have to know the short circuit AVAILABLE fault current of the SOURCE. Once you know that you can solve the problem. You can use CYME (tm) or if you know the available high side fault current (the electric company can tell you) then u can use the FREE EATON fault current I Phone AP to get the answer. The AP is available in the Apple(tm) Store or www.eaton.com/us/en-us/products/electrical-circuit-protection/fuses/fault-current-calculator.html. Once again, you need to know the available fault current of the source to get the answer. Why do u need to know this? Suppose there's a 25 KVA pole transformer, 7.2 KV primary, 120/240 secondary,100 feet of 1/0 TPX to the weather-head and 100 feet of #2 CU to the main breaker in the load center. The electrical inspector needs to know what is the available fault current at the panel. If it's under 10 KA, then u can use off the shelf breakers from the home center. If its over 10 KA but less than 22 KA, then you need more expensive breakers that can handle the predicted fault current. The electrician needs to know this too. When the primary is 19.9 KV phase to neutral, the available fault currents are always high.