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Home / Technical Articles / Overcurrent protection of transformer (NEC 450.3)

NEC 450.3

The overcurrent protection required for transformers is consider for Protection of Transformer only. Such overcurrent protection will not necessarily protect the primary or secondary conductors or equipment connected on the secondary side of the transformer.

Overcurrent protection of transformer (NEC 450.3)
Overcurrent protection of transformer (NEC 450.3) – photo credit: designworldonline.com

Content


Introduction

The overcurrent protection required for transformers is consider for Protection of Transformer only. Such overcurrent protection will not necessarily protect the primary or secondary conductors or equipment connected on the secondary side of the transformer.

When voltage is switched on to energize a transformer, the transformer core normally saturates.

This results in a large inrush current which is greatest during the first half cycle (approximately 0.01 second) and becomes progressively less severe over the next several cycles (approximately 1 second) until the transformer reaches its normal magnetizing current. To accommodate this inrush current, fuses are often selected which have time-current withstand values of at least 12 times transformer primary rated current for 0.1 second and 25 times for 0.01 second. Some small dry-type transformers may have substantially greater inrush currents.

To avoid using over sized conductors, overcurrent devices should be selected at about 110 to 125 percent of the transformer full-load current rating. And when using such smaller overcurrent protection, devices should be of the time-delay type (on the primary side) to compensate for inrush currents which reach 8 to 10 times the full-load primary current of the transformer for about 0.1 s when energized initially.

Protection of secondary conductors has to be provided completely separately from any primary-side protection.

A supervised location is a location where conditions of maintenance and supervision ensure that only qualified persons will monitor and service the transformer installation. Overcurrent protection for a transformer on the primary side is typically a circuit breaker. In some instances where there is not a high voltage panel, there is a fused disconnect instead.

It is important to note that the overcurrent device on the primary side must be sized based on the transformer KVA rating and not sized based on the secondary load to the transformer.

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Overcurrent Protection of Transformers >600V (NEC450.3A)

1) Unsupervised Location of Transformer (Impedance <6%)

Unsupervised Location of Transformer (Impedance <6%)
Unsupervised Location of Transformer (Impedance <6%)

  • OverCurrent Protection at Primary Side (Primary Voltage >600V):
  • Rating of Pri. Fuse at Point A= 300% of Pri. Full Load Current or Next higher Standard size. or
  • Rating of Pri. Circuit Breaker at Point A= 600% of Pri. Full Load Current or Next higher Standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage <=600V):
  • Rating of Sec. Fuse / Circuit Breaker at Point B= 125% of Sec. Full Load Current or Next higher Standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage >600V):
  • Rating of Sec. Fuse at Point B= 250% of Sec. Full Load Current or Next higher Standard size. or
  • Rating of Sec. Circuit Breaker at Point B= 300% of Sec. Full Load Current.
Example: 750KVA, 11KV/415V 3Phase Transformer having Impedance of Transformer 5%

  • Full Load Current At Primary side = 750000/(1.732X11000) = 39A
  • Rating of Primary Fuse = 3X39A = 118A, So Standard Size of Fuse = 125A.
  • OR Rating of Primary Circuit Breaker = 6X39A = 236A, So standard size of CB = 250A.
  • Full Load Current at Secondary side = 750000/(1.732X415)  = 1043A.
  • Rating of Secondary of Fuse / Circuit Breaker = 1.25X1043A = 1304A, so standard size of Fuse = 1600A.

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2) Unsupervised Location of Transformer (Impedance 6% to 10%)

Unsupervised Location of Transformer (Impedance 6% to 10%)
Unsupervised Location of Transformer (Impedance 6% to 10%)

  • OverCurrent Protection at Primary Side (Primary Voltage >600V):
  • Rating of Pri. Fuse at Point A= 300% of Primary Full Load Current or Next higher Standard size.
  • Rating of Pri. Circuit Breaker at Point A= 400% of Primary Full Load Current or Next higher Standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage <=600V):
  • Rating of Sec. Fuse / Circuit Breaker at Point B= 125% of Sec. Full Load Current or Next higher Standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage >600V):
  • Rating of Sec. Fuse at Point B= 225% of Sec. Full Load Current or Next higher Standard size.
  • Rating of Sec. Circuit Breaker at Point B= 250% of Sec. Full Load Current or Next higher Standard size.
Example: 10MVA, 66KV/11KV 3Phase Transformer, Impedance of Transformer is 8%

  • Full Load Current At Primary side = 10000000/(1.732X66000) = 87A
  • Rating of Pri.  Fuse = 3X87A = 262A, so next standard size of Fuse = 300A.
  • OR Rating of Pri. Circuit Breaker = 6X87A = 525A, so next standard size of CB = 600A.
  • Full Load Current at Secondary side = 10000000/(1.732X11000) = 525A.
  • Rating of Sec. Fuse = 2.25X525A = 1181A, so next standard size of fuse = 1200A.
  • OR Rating of Sec. Circuit Breaker = 2.5X525A = 1312A, so next standard size of circuit breaker = 1600A.

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3) Supervised Location (in Primary side only) of Transformer

Supervised Location (in Primary side only) of Transformer
Supervised Location (in Primary side only) of Transformer

  • OverCurrent Protection at Primary Side (Primary Voltage >600V):
  • Rating of Pri. Fuse at Point A= 250% of Primary Full Load Current or Next higher Standard size.
  • Rating of Pri. Circuit Breaker at Point A= 300% of Primary Full Load Current or Next higher Standard size.

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4) Supervised Location of Transformer (Impedance Up to 6%)

Supervised Location of Transformer (Impedance Up to 6%)
Supervised Location of Transformer (Impedance Up to 6%)

  • OverCurrent Protection at Primary Side (Primary Voltage >600V):
  • Rating of Pri. Fuse at Point A= 300% of Pri. full load current or next lower standard size.
  • Rating of Pri. Circuit Breaker at Point A= 600% of Pri. full load current or next lower standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage <=600V):
  • Rating of Sec. Fuse / Circuit Breaker at Point B= 250% of Sec. Full Load Current or Next higher Standard size.
  • OverCurrent Protection at Secondary Side (Secondary Voltage >600V):
  • Rating of Sec. Fuse at Point B= 250% of Sec. Full Load Current or Next Lower Standard size.
  • Rating of Sec. Circuit Breaker at Point B= 300% of Sec. Full Load Current or Next Lower Standard size.
Example: 750KVA, 11KV/415V 3Phase Transformer having Impedance of Transformer 5%

  • Full Load Current At Primary side = 750000/(1.732X11000) = 39A
  • Rating of Primary Fuse = 3X39A = 118A, so next lower standard size of fuse = 110A.
  • OR Rating of Primary Circuit Breaker = 6X39A = 236A, so next lower standard size of Circuit Breaker = 225A.
  • Full Load Current at Secondary side = 750000/(1.732X415) =1043A.
  • Rating of Secondary of Fuse / Circuit Breaker = 2.5X1043A=2609A, so standard size of Fuse = 2500A.

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5) Supervised Location of Transformer (Impedance 6% to 10%)

Supervised Location of Transformer (Impedance 6% to 10%)
Supervised Location of Transformer (Impedance 6% to 10%)

  • OverCurrent Protection at Primary Side (Primary Voltage >600V):
  • Rating of Pri. Fuse at Point A= 300% of Pri. full load current or next lower standard size.
  • Rating of Pri. Circuit Breaker at Point A= 400% of Pri. full load current or next lower standard size.
  • Overcurrent protection at secondary side (Secondary voltage <=600V):
  • Rating of Sec. Fuse / Circuit Breaker at Point B= 250% of Sec. full load current or next higher standard size.
  • Overcurrent protection at secondary side (Secondary voltage >600V):
  • Rating of Sec. Fuse at Point B= 225% of Sec. full load current or next lower standard size.
  • Rating of Sec. Circuit Breaker at Point B= 250% of Sec. full load current or next lower standard size.
Example: 750KVA, 11KV/415V 3Phase Transformer having Impedance of Transformer 8%

  • Full Load Current At Primary side = 750000/(1.732X11000) = 39A
  • Rating of Primary Fuse = 3X39A = 118A, so next lower standard size of Fuse = 110A.
  • OR Rating of Primary Circuit Breaker = 4X39A = 157A, so next lower standard size of Circuit Breaker = 150A.
  • Full Load Current at Secondary side = 750000/(1.732X415) = 1043A.
  • Rating of Secondary of Fuse / Circuit Breaker = 2.5X1043A=2609A, so standard size of Fuse = 2500A.

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Difference in C.B between Supervised & Unsupervised Location

Here we see two notable conditions while we select Fuse / Circuit Breaker in Supervised Location and Unsupervised Location.

First notable condition is Primary Overcurrent Protection. In unsupervised location fuse in primary side is 300% of primary current or Next Higher Standard size and in supervised location is 300% of primary current or Next Lower Standard size. Here primary overcurrent protection is same in both conditions (300%), but selecting size of Fuse/Circuit Breaker is different.

Lets us Check with the Example for 750KVA, 11KV/415V 3Phase Transformer.

  • Full Load Current At Primary side = 750000/(1.732X11000) = 39A
  • In Unsupervised Location: Rating of Primary Fuse = 3X39A = 118A, so next higher standard size = 125A
  • In Supervised Location: Rating of Primary Fuse = 3X39A = 118A, so next lower standard size = 110A
  • Second notable condition is Secondary Overcurrent Protection increased from 125% to 250% for unsupervised to Supervised Location.

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Summary of overcurrent Protection for more than 600V

Maximum Rating of Overcurrent Protection for Transformers more than 600 Volts
Location LimitationsTransformer Rated ImpedancePrimary Protection
(More than 600 Volts)
Secondary Protection
More than 600VLess than 600V
C. B.Fuse RatingC. B.Fuse RatingC.B or Fuse
Any locationLess than 6%600%(NH)300%(NH)300 %( NH)250%(NH)125%(NH)
6% To 10%400%(NH)300%(NH)250%(NH)225%(NH)125%(NH)
Supervised locations onlyAny300%(NH)250%(NH)Not requiredNot requiredNot required
Less than 6%600%300%300%250%250%
6% To 10%400%300%250%225%250%
NH: Next Higher Standard Size.

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Overcurrent Protection of transformers <600V (NEC 450.3B)

1) Only Primary side Protection of Transformer

Only Primary side Protection of Transformer
Only Primary side Protection of Transformer

  • OverCurrent Protection at Primary Side (Less than 2A):
  • Rating of Pri. Fuse / C.B at Point A = 300% of Pri. full load current or next lower standard size.
  • Example: 1KVA, 480/230 3Phase transformer, full load current at Pri. side = 1000/(1.732X480) = 1A
  • Rating of Primary Fuse = 3X1A = 3A, so next lower standard size of Fuse = 3A.
  • OverCurrent Protection at Primary Side (2A to 9A):
  • Rating of Sec. Fuse / C.B at Point A = 167% of Pri. full load current or next lower standard size.
  • Example: 3KVA, 480/230 3Phase transformer, full load current at Pri. side = 3000/(1.732X480) = 4A
  • Rating of Primary Fuse = 1.67X4A = 6A, so next lower standard size of Fuse = 6A.
  • OverCurrent Protection at Primary Side (More than 9A):
  • Rating of Pri. Fuse / C.B at Point A = 125% of Pri. full load current or next higher standard size.
  • Example: 15KVA, 480/230 3Phase transformer, full load current at Pri. side = 15000/(1.732X480) = 18A
  • Rating of Primary Fuse = 1.25X18A= 23A, so next higher standard size of Fuse = 25A.

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2) Primary and Secondary side Protection of Transformer

Primary and Secondary side Protection of Transformer
Primary and Secondary side Protection of Transformer

  • OverCurrent Protection at Primary Side (Less than 2A):
  • Rating of Pri. Fuse / C.B at Point A = 250% of Pri. full load current or next lower standard size.
  • OverCurrent Protection at Primary Side (2A to 9A):
  • Rating of Sec. Fuse / C.B at Point A= 250% of Pri. full load current or next lower standard size.
  • OverCurrent Protection at Primary Side (More than 9A):
  • Rating of Pri. Fuse / C.B at Point A= 250% of Pri. Full Load Current or Lower Higher Standard size.
  • Example: 25KVA, 480/230 3Phase Transformer, Full Load Current at Pri. Side=125000/(1.732X480)=30A
  • Rating of Primary Fuse = 2.50X30A= 75A, So Next Lower Standard Size of Fuse =70A.
  • OverCurrent Protection at Secondary Side (Less than 9A):
  • Rating of Pri. Fuse / C.B at Point B= 167% of Sec. Full Load Current or Lower Standard size.
  • Example: 3KVA, 480/230 3Phase Transformer, Full Load Current at Sec. Side=3000/(1.732X230)=8A
  • Rating of Primary Fuse = 1.67X8A= 13A, So Next Lower Standard Size of Fuse =9A.
  • OverCurrent Protection at Secondary Side (More than 9A):
  • Rating of Pri. Fuse / C.B at Point A= 125% of Pri. Full Load Current or Higher Standard size.
  • Example: 15KVA, 480/230 3Phase Transformer, Full Load Current at Sec. Side=15000/(1.732X230)=38A
  • Rating of Primary Fuse = 1.25X38A= 63A, So Next Higher Standard Size of Fuse =70A.

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Summary of overcurrent Protection for Less than 600V

Maximum Rating of Overcurrent Protection for Transformers Less than 600 Volts
Protection MethodPrimary ProtectionSecondary Protection
More than 9A2A to 9ALess than 2AMore than 9ALess than 9A
Primary only protection125%(NH)167%300%Not requiredNot required
Primary and secondary protection250%250%250%125%(NH)167%
NH: Next Higher Standard Size.

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Jignesh Parmar

Jignesh Parmar has completed M.Tech (Power System Control), B.E (Electrical). He is member of Institution of Engineers (MIE), India. He has more than 20 years experience in transmission & distribution-energy theft detection and maintenance electrical projects.

23 Comments


  1. Kevin Young
    Nov 09, 2021

    In your last example, there appears to be a typo mistake:
    “Rating of Primary Fuse = 1.25X38A= 63A”
    63A should be 47.5A.


  2. Ruben Perez Perdomo
    Sep 17, 2021

    I tried a couple of times to save to PDF this article but I was not able to. I became a premium member yesterday. For my understanding change the article to PDF is part of the subscription

    Please advise.

    is there other articles that you recommend regarding transformer protection?

    Thank you


  3. Samuel Adjei
    Sep 10, 2020

    What will be fuse rating 100kva at 33/0.433kv?
    thanks


    • avn sridhar
      Oct 05, 2020

      Sir, Let me know the recommended fuse for 100 kvA – 3 pole ; 33kV HV & LV: 440 V .
      Thanks.

      Sridhar


  4. gfdg
    Nov 05, 2019

    Great explanation. Do you have a BibTex that I can use for my publications?
    Because I am willing to use your work as a reference to my work.


  5. C J Cooney
    Mar 25, 2017

    Hi. A ton of good information here.

    I am reading the very beginning.

    “This results in a large inrush current which is greatest during the first half cycle (approximately 0.01 second) and becomes progressively less severe over the next several cycles (approximately 1 second) until the transformer reaches its normal magnetizing current.” You think flux builds up over multiple cycles? Anything is saved or stored in a transformer from cycle to cycle?

    “Such overcurrent protection will not necessarily protect the primary or secondary conductors or equipment connected on the secondary side of the transformer.

    To avoid using over sized conductors, overcurrent devices should be selected at about 110 to 125 percent of the transformer full-load current rating.”

    You make the good point that the protection is for the transformer and may or may not protect the conductors. But then why the “over sized conductors” comment? The 125% is for the transformer.


  6. Sudipta
    Oct 01, 2015

    We have one three winding transformer 75/60/45MVA, 220/11/11kV, Pri to sec. and Pri. to Ter. % impedance 13.2. Secondary current 1080/1440/1800A and primary 196A.

    Please give overcurrent and short circuit setting of primary and secondary side of transformer.


  7. Arun goel
    Aug 15, 2015

    Article is very useful.


  8. Ray
    May 29, 2015

    Thank you for this. I found the article to be very helpful though you may want to double check your math in the last example. Specifically the item below should be 47.5A not 63A so you would need a 50A Fuse instead of 70A.

    Rating of Primary Fuse = 1.25X38A= 63A, So Next Higher Standard Size of Fuse =70A.


  9. Engr. Enrique Flores
    May 26, 2015

    Engr. Parmar,

    Have you done a good work here.

    Thanks for sharing.

    Regards,

    Enrique Flores, PEE


  10. Carlos Lover
    May 24, 2015

    Mr. Engineer

    Please please show if a line of medium voltage 22.9 kV system with isolated neutral delta in 22.9, with transformer Delta-Star (22.9-0.22 kV) is required to implement protection ground fault line in the beginning of the line 22.9 kV, if applicable type of protection that should be placed (ie relay function). If you can publish an article on this subject is appreciated.

    Thank you for your attention


  11. Ian
    Apr 06, 2015

    Per NEC 240.4(F)code it states primary side OCP is only allowed on delta-delta and not delta-wye. This caveat should be listed at 3) Supervised Location (in Primary side only) of Transformer


  12. Ajay John
    Jan 26, 2015

    Dear Parmar,what about the over protection of transformer with respect of IEC following countries?.Whether there is any connection and formula for design of the transformer protection circuits?


  13. Ricardo Brown
    Jan 20, 2015

    Mr Engineer
    I am looking for a simulator program that can detect faults scenario that can exit on a single phase or three phase transformers


  14. Krishna
    Nov 15, 2014

    Thanks a lot, it’s very useful me.


  15. Tam
    Oct 22, 2014

    Hi,
    Engineer is looking for fuses to protect 25KV primary transformer for railway industry.
    63kA; 1500V AC BS2692 part-1
    50KA; 660V DC BS88-part-1
    Thanks for information please contact us if any, kind of this product available.
    Regards,


  16. Lona
    Jul 22, 2014

    Hi

    Tks so much for such educating website. I’ve got only 1 question – what do you mean by supervised and unsupervised locations.


    • Satyajit Sahoo
      May 07, 2020

      A supervised location is a location where conditions of maintenance and supervision ensure that only qualified persons will monitor and service the transformer installation. Overcurrent protection for a transformer on the primary side is typically a circuit breaker. In some instances where there is not a high voltage panel, there is a fused disconnect instead.


  17. David S
    Feb 26, 2014

    In your example of “OverCurrent Protection at Primary Side (More than 9A)” why did you use 125000 instead of 25000 (25KVA) in your calculation of the full load current at the primary side?


  18. Mohit Bhatia
    Jun 19, 2013

    Nice Article.
    But I understand this article is related to component sizing selection (Fuse and CB) not Overcurrent protection.
    e.g. This article explained the selection of FUSE rating, CB rating only. it doesn;t explain the protection setting (Pick Up point for Inst and IDMT).
    If there any article for Overcurrent Protection for transformer Setting (Instantaneous and IDMT), please share.


  19. chourishiraj
    Jun 17, 2013

    How can we calculate the power losses due to harmonics in the power system or power equipment like Transformer, cables, motors, etc. please reply


  20. CHAKWESHA CHAKWESHA
    Oct 09, 2012

    This is a very good website.I really enjoy logging to it.


    • Edvard
      Oct 09, 2012

      Thank you Chakwesha! Glad you find EEP usefull for your education/work. Technical writers like Jignesh and others are really contrubuting a lot.

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