MV/LV transformer protection against temperature rise, overloads, short-circuit & overvoltages

When selecting the type of transformer correctly electrical engineer needs to know its different electrical and thermal properties and the resistance to stresses due to faults or normal service of... Read more

The post MV/LV transformer protection against temperature rise, overloads, short-circuit & overvoltages appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/mv-lv-transformer-protection
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Busbar protection schemes for distribution substations

Busbars play an important role in power transmission and distribution. They are employed as a central distribution point for all feeders. In the case of a fault, current on the... Read more

The post Busbar protection schemes for distribution substations appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/busbar-protection-schemes
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

What is Correct Method of MCB Connections

Introduction:

  • MCB is a mechanical switching device which can carry and break currents under normal circuit conditions and also under specified abnormal conditions, such as overload and short circuit.
  • The MCB can provide protection until and unless we have install input power (LINE) connection and Output (LOAD) connections in proper Terminals of MCB.
  • Electrical engineers seem to be confused to indentify where is the Line and Load terminal of an MCB (on the top or on the bottom).

Terminal Marking of MCB:

  • There are two type of MCB available in market.
  • MCB having terminal marking (LINE / LOAD Marking) (Polarized MCB)
  • MCB having No terminal marking (No any Marking) (Non Polarized MCB)
  • Some manufacture clearly indicates where to apply Input Power and where to connect Load on MCB while some manufacture does not indicate such Terminal Marking.
  • The constructions of both MCB are almost same even though we need to understand difference between them.

(1) LINE / LOAD Terminal Marking on MCB (Polarized MCB)

  • For AC Circuit:
  • If manufactures indicate Input (LINE) making on MCB then we have to give Supply at “LINE” Terminal and Load at “LOAD” Terminal for perfect operation of MCB.
  • If we do wrong connection than MCB may or may not give proper protection in fault Condition.
  • As Per UL 489 Paragraph 9.1.1.13: It is clearly indicate that “Circuit breakers shall be marked “Line” and “Load” unless the construction and test results are acceptable with the line and load connections reversed. This marking requirement specifies that UL MCB shall be marked with the word “Line” on one end of the circuit breaker and the word “Load” on the other end”, as shown in Figure

111

  • If MCB is not live (ON) from long time (in Cold state) than there is possibility of MCB to not operate in fault conditions.
  • In MCB ,The fixed contact is encompassed by the arc chute, and the arc products are de ionized, cooled and ejected uneventfully when the incoming power is on “Line” Terminal (when the fixed contact is ‘live’ or ‘hot’).There is less chance to re strike arc again.
  • If the power is applied to moving contact ,”Load” Terminal, the flexible connector, the trip system, everything is live/hot after the arc is quenched. Chances of restrike/flashover are much higher.
  • For DC Circuit:
  • The polarized DC MCB have a marking of ‘+’ and ‘–‘ symbol
  • If Polarized DC MCB are wired incorrectly, they are a possibility of hazard and When we turned off under load, the MCB might not be able to extinguish the arc and the circuit breaker will burn out.
  • Polarized DC MCB use a small magnet to direct the arc away from the contacts and up into the arc shoot and arc disrupter cage. If the direction of current flow through the unit is reversed, then the magnet directs the arc away from the arc shoot and into the mechanism of the unit thus destroying it.

2

(2) No Terminal Marking on MCB (Non Polarized MCB)

  • For AC Circuit:
  • If manufacture has not indicated any Terminal Marking than we are free to connect line or load at any side as we wish.
  • If construction / Operating principle of both MCB are same then what are the different between them.
  • Without Terminal Marking MCB has following additional features.
  • (1) By Design improvement (Manufacture has provided some more provision for quenching of arc (So it cannot reproduce it again).
  • (2) By doing some more extra test as per IEC 60947-2 and UL 489

3

  • The performance of single-break circuit breakers is slightly different when the “LINE” and “LOAD” feed either from the bottom or Top hence IEC 60947-2 specifies that one additional SC test be carried out with connections required when the terminals are not specifically marked ‘Line’ and/or ‘Load’

Table 10- Number of samples for test (IS / IEC 60947-2)

Test Sequences

Terminal Marking (Line / Load) No of Sample for Testing

 

Sample For *

 

YES

NO

 In

1 1
Ics (Rated service short-circuit breaking capacity)  (Ics=25%Icu)

2 1
2

3 1
2
3

3 1
2
3

4 1
2
3
4
Icu  (Rated ultimate short-circuit breaking capacity)

2 1
2

3 1
2
3

3 1
2
3

4 1
2
3
4
* Sample For Indications
1 In of a given frame size.
2 This sample is omitted in the following cases:
A circuit-breaker having a single non-adjustable current setting for a given frame size;
A circuit-breaker provided only with a shunt release (i.e. without an integral over current release);
A circuit-breaker with electronic over current protection, of a given frame size, having an adjustable current rating by electronic means only (i.e. without change of current sensors).
3 Connections reversed.
4 Connections reversed, if terminals unmarked.
  • As Per UL 489, Paragraph 7.1.1.18: “if a circuit breaker is not marked “Line” and “Load,” one sample of each set tested, or one additional sample, shall be connected with the line and load connections reversed during the overload, endurance and interrupting tests”.
  • This UL test requirement specifies that for MCC to be UL Listed for reverse-feed applications, samples shall be tested with the line and load terminals reverse-fed, as shown in Figure, and that the test results shall be the same as those of “normally” fed circuit breakers. Depending on the design configuration and construction, the circuit breaker may or may not be affected by the application of power in a reverse-feed connection during these tests.

4

  • If Line / Load are not marked, we can connect Line or Load either on Top or bottom of MCB. However, it is a good practice to keep the fixed contact side connected to the bus bar.
  • For DC Circuit:
  • The Non polarized DC MCB have a No marking as ‘+’ and ‘–‘ symbol
  • Non polarized DC MCB operate safely as load breaking isolators and for fault current protection regardless of the direction of current flow through them.

5

Conclusion:

  • When a MCB are marked “Line” and “Load,” the power supply conductors must be connected to the marked “Line.” These MCB cannot be reverse-fed.
  • If “Line” and “Load” are not marked on MCB, the power supply conductors may be connected to either end. These devices are suitable for reverse-feed applications.


September 20, 2018 at 11:47PM by Department of EEE, ADBU: https://ift.tt/2AyIRVT

How to know if you set the correct current on a motor thermal overload relay

The full-load current at a given voltage indicated on the nameplate is normative for setting the overload relay. Because of the variable voltages around the world, motors for pumps are... Read more

The post How to know if you set the correct current on a motor thermal overload relay appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/current-set-motor-overload-relay
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Secondary equipment you should always consider when retrofitting existing HV substation

This approach assumes retrofitting and upgrading old substation secondary equipment such as intelligent electronic devices (IEDs), monitoring sensors, power apparatus, communication protocol and operating standards to improve the overall performance... Read more

The post Secondary equipment you should always consider when retrofitting existing HV substation appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/secondary-equipment-retrofitting-hv-substation
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

DC versus AC power transmission with reference to bulk-energy transfer

High voltage transmission systems has a dual purpose, i.e. system interconnection and bulk-energy transfer. With reference to system interconnection, the need to operate the whole system in perfect synchronism often... Read more

The post DC versus AC power transmission with reference to bulk-energy transfer appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/dc-versus-ac-power-transmission
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Relay settings and applying high-impedance differential busbar protection scheme

The most of HV busbur faults involve single phase and earth, but faults may arise from many different causes. The number of faults that stand out is between phases clear... Read more

The post Relay settings and applying high-impedance differential busbar protection scheme appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/high-impedance-differential-protection-busbar
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Earth fault protection of an AC motor in 4 different earthing systems

One of the most common faults to occur on a motor is a stator winding fault. Whatever the initial form of the fault (phase phase, etc.) or the cause (cyclic... Read more

The post Earth fault protection of an AC motor in 4 different earthing systems appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/earth-fault-protection-ac-motor
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Pirating of Technical Works-2

It has been observed that some website totally copy paste of this blog and parallel republished all posts of this blog again on their commercial website  .

Lots of time has been spent to read Books,Manuals,Handbooks and combined it with  practical experience to serve Handy Electrical tools,Notes to serve the Electrical Community.This Blog is a fusion of Theoretical and Practically knowledge to make all technical things easier to understand.

Please look at following totally copy paste material of  this  Blog. 

Originally published

(1) https://electricalnotes.wordpress.com/2016/10/04/how-to-select-mcb-mccb-part1/

(2) https://electricalnotes.wordpress.com/2013/06/02/calculate-size-of-contactor-fuse-c-b-over-load-relay-of-dol-starter/

 

Totally copy past link on website ( http://controlmakers.ir/en/)

(1) http://controlmakers.ir/en/how-to-select-mcb-mccb/

(2) http://controlmakers.ir/en/calculate-size-of-contactor-fuse-c-b-over-load-relay-of-dol-starter/

Totally Copy & Paste word by word

 



September 09, 2018 at 11:40PM by Department of EEE, ADBU: https://ift.tt/2AyIRVT

Applying CTs in protection schemes for transformers, generators, machines etc.

Various types of instrument transformers are currently in use on the basis of the varied applications of these devices. The construction aspects and sizing play an important role in the... Read more

The post Applying CTs in protection schemes for transformers, generators, machines etc. appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/cts-protection-schemes
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

The essentials of electrical distribution systems every engineer should know

Electrical distribution systems are an essential part of the electrical power system. In order to transfer electrical power from an alternating current (AC) or a direct current (DC) source to... Read more

The post The essentials of electrical distribution systems every engineer should know appeared first on EEP - Electrical Engineering Portal.


View more at https://electrical-engineering-portal.com/electrical-distribution-systems
Credit- Electrical Engineering Portal. Published by Department of EEE, ADBU: tinyurl.com/eee-adbu

Calculate Size of Contactor / Fuse / CB / OL Relay of Star-Delta Starter

  • Calculate Size of each Part of Star-Delta starter for 10HP, 415 Volt Three Phase Induction Motor having Non Inductive Type Load, Code A, Motor efficiency 80%, Motor RPM 600, Power Factor 0.8. Also Calculate Size of Overload Relay if O/L Relay Put in the wingdings (overload is placed after the Winding Split into main and delta Contactor) or in the line (Putting the overload before the motor same as in DOL).

 

Basic Calculation of Motor Torque & Current:

  • Motor Rated Torque (Full Load Torque) =5252xHPxRPM
  • Motor Rated Torque (Full Load Torque)=5252x10x600=88 lb-ft.
  • Motor Rated Torque (Full Load Torque) =9500xKWxRPM
  • Motor Rated Torque (Full Load Torque)=9500x(10×0.746)x600 =119 Nm
  • If Motor Capacity is less than 30 KW than Motor Starting Torque is 3xMotor Full Load Current or 2X Motor Full Load Current.
  • Motor Starting Torque=3x Motor Rated Torque (Full Load Torque).
  • Motor Starting Torque==3×119=356 Nm.
  • Motor Lock Rotor Current =1000xHPx figure from below Chart/1.732×415
Locked Rotor Current
Code Min Max
A 1 3.14
B 3.15 3.54
C 3.55 3.99
D 4 4.49
E 4.5 4.99
F 5 2.59
G 2.6 6.29
H 6.3 7.09
I 7.1 7.99
K 8 8.99
L 9 9.99
M 10 11.19
N 11.2 12.49
P 12.5 13.99
R 14 15.99
S 16 17.99
T 18 19.99
U 20 22.39
V 22.4
  • As per above chart Minimum Locked Rotor Current =1000x10x1/1.732×415=14 Amp
  • Maximum Locked Rotor Current =1000x10x3.14/1.732×415=44 Amp.
  • Motor Full Load Current (Line) =KWx1000/1.732×415
  • Motor Full Load Current (Line) = (10×0.746)x1000/1.732×415=13 Amp.
  • Motor Full Load Current (Phase) =Motor Full Load Current (Line)/1.732.
  • Motor Full Load Current (Phase) ==13/1.732=7 Amp.
  • Motor Starting Current (Star-Delta Starter) =3xFull Load Current.
  • Motor Starting Current (Line)=3×13=39 Amp

(1) Size of Fuse:

Fuse  as per NEC 430-52
Type of Motor Time Delay Fuse Non-Time Delay Fuse
Single Phase 300% 175%
3 Phase 300% 175%
Synchronous 300% 175%
Wound Rotor 150% 150%
Direct Current 150% 150%
  • Maximum Size of Time Delay Fuse =300% x Full Load Line Current.
  • Maximum Size of Time Delay Fuse =300%x13= 39 Amp.
  • Maximum Size of Non Time Delay Fuse =1.75% x Full Load Line Current.
  • Maximum Size of Non Time Delay Fuse=1.75%13=23 Amp.

(2) Size of Circuit Breaker:

Circuit Breaker as per NEC 430-52
Type of Motor Instantaneous Trip Inverse Time
Single Phase 800% 250%
3 Phase 800% 250%
Synchronous 800% 250%
Wound Rotor 800% 150%
Direct Current 200% 150%
  • Maximum Size of Instantaneous Trip Circuit Breaker =800% x Full Load Line Current.
  • Maximum Size of Instantaneous Trip Circuit Breaker =800%x13= 104 Amp.
  • Maximum Size of Inverse Trip Circuit Breaker =250% x Full Load Line Current.
  • Maximum Size of Inverse Trip Circuit Breaker =250%x13= 32 Amp.

(3) Thermal over Load Relay:

Thermal over Load Relay (Phase):

  • Min Thermal Over Load Relay setting =70%xFull Load Current(Phase)
  • Min Thermal Over Load Relay setting =70%x7= 5 Amp
  • Max Thermal Over Load Relay setting =120%xFull Load Current(Phase)
  • Max Thermal Over Load Relay setting =120%x7= 9 Amp

Thermal over Load Relay (Line):

  • For a star-delta starter we have the possibility to place the overload protection in two positions, in the line or in the windings.
  • If O/L Relay Placed in Line: (Putting the O/L before the motor same as in DOL).Supply>Over Load Relay>Main Contactor
  • If Over Load Relay supply the entire motor circuit and are located ahead of where the power splits to the Delta and Star contactors, so O/L Relay size must be based upon the entire motor Full Load Current.
  • Thermal over Load Relay setting =100%xFull Load Current (Line).
  • Thermal over Load Relay setting =100%x13= 13 Amp
  • Disadvantage: O/L Relay will not give Protection while Motor runs in Delta (Relay Setting is too High for Delta Winding)
  • If O/L Relay Placed In the windings: (overload is placed after the Winding Split into main and delta Contactor).Supply>Main Contactor-Delta Contactor>O/L Relay
  • If overload is placed after the Point where the wiring Split into main and delta Contactor, Size of over load relay at 58% (1/1.732) of the motor Full Load Current because we use 6 leads going to the motor, and only 58% of the current goes through the main set of conductors (connected to the main contactor).
  • The overload then always measures the current inside the windings, and is thus always correct. The setting must be x0.58 FLC (line current).
  • Thermal over Load Relay setting =58%xFull Load Current (Line).
  • Thermal over Load Relay setting =58%x13= 8 Amp.
  • Disadvantage: We must use separate short-circuit and overload protections

(4) Size and Type of Contactor:

  • Main and Delta Contactor:

  • The Main and Delta contactors are smaller compared to single contactor used in a Direct on Line starter because they Main and Delta contactors in star delta starter are controlling winding currents only. The currents through the winding are 1/√3 (58%) of the current in the line. These two contactors (Main contactor and Delta Contactor) are close during run. These rated at 58% of the current rating of the motor.
  • Star Contactor:

  • The third contactor is the star contactor and that only carries star current while the motor is connected in star in starting. The current in star winding is 1/√3= (58%) of the current in delta, so this contactor can be rated at 1/3 (33%) of the motor rating. Star contactor can be selected smaller than the others, providing the star contactor pulls first before the main contactor. Then no current flows when third contactor pulls.
  • In star connection at start, the motor draws and delivers 1/3 of its full rated power.
  • When the starter switches over to Delta, the motor draws full power, but since the contactors and the overload relay are usually wired within the Delta, you need to use contcators and relay which are only rated 1/√3 =58% of the full rated power of the motor.
Application Contactor Making Cap
Non-Inductive or Slightly Inductive ,Resistive Load AC1 1.5
Slip Ring Motor AC2 4
Squirrel Cage Motor AC3 10
Rapid Start / Stop AC4 12
Switching of Electrical Discharge Lamp AC5a 3
Switching of Electrical Incandescent Lamp AC5b 1.5
Switching of Transformer AC6a 12
Switching of Capacitor Bank AC6b 12
Slightly Inductive Load in Household or same type load AC7a 1.5
Motor Load in Household Application AC7b 8
Hermetic refrigerant Compressor Motor with Manual O/L Reset AC8a 6
Hermetic refrigerant Compressor Motor with Auto O/L Reset AC8b 6
Control of Restive & Solid State Load with opto coupler Isolation AC12 6
Control of Restive Load and Solid State with T/C Isolation AC13 10
Control of Small Electro Magnetic Load ( <72VA) AC14 6
Control of Small Electro Magnetic Load ( >72VA) AC15 10
  • As per above Chart
  • Type of Contactor= AC1
  • Making/Breaking Capacity of Contactor= Value above Chart x Full Load Current (Line).
  • Making/Breaking Capacity of Contactor=1.5×13= 19 Amp.
  • Size of Star Contactor (Starting Condition) = 33%X Full Load Current (Line).
  • Size of Star Contactor =33%x13 = 4 Amp.
  • Size of Main Contactor (Starting-Transition-Running) = 58%X Full Load Current (Line).
  • Size of Main Contactor =58%x13 = 8 Amp.
  • Size of Delta Contactor (Running Condition) = 58%X Full Load Current (Line).
  • Size of Delta Contactor =58%x13 = 8 Amp.

Summary:

  •  Type of Contactor= AC1
  • Making/Breaking Capacity of Contactor=19 Amp.
  • Size of Star Contactor =4 Amp.
  • Size of Main Contactor = 8 Amp.
  • Size of Delta Contactor =8 Amp.


September 01, 2018 at 12:13AM by Department of EEE, ADBU: https://ift.tt/2AyIRVT