Wednesday, August 28, 2013

Basics of Circuit Breakers (Rockwell Automation)

Basics of Circuit Breakers

Content:

1. Design, function and types of

circuit breakers 1.1

1.1. Summary 1.1

1.2. Types of switches 1.2

1.2.1. Manual motor starter and protector or

circuit breaker with motor protective characteristics 1.2

1.2.2. Circuit breaker 1.2

1.2.3. Load break switch 1.6

1.2.4. Disconnector 1.6

1.2.5. Main switch 1.7

1.2.6. Emergency OFF-switch 1.8

1.2.7. Summary: Circuit breaker as load break switch 1.8

1.3. Design of a circuit breaker 1.9

1.3.1. The current path of the circuit breaker 1.9

1.3.2. Thermal overload release 1.10

1.3.3. Electromagnetic overcurrent release 1.10

1.3.4. Main contact system 1.12

1.3.5. Auxiliary contacts 1.15

1.3.6. Operating mechanism 1.15

1.4. Functions of a circuit breaker 1.15

1.4.1. Interrupting short-circuit current 1.16

1.4.2. Reliable protection of motors 1.17

1.4.3. Protection of leads and its optimum utilisation 1.18

1.4.4. Protection of installations 1.19

1.4.5. Integration in the control circuit 1.19

1.4.6. Switching under normal service conditions 1.20

1.4.7. Disconnecting function 1.20

1.4.8. Locking out with a padlock 1.20

2. Circuit breaker technology 2.1

2.1. Summary 2.1

2.2. Short-circuit current in supply systems 2.2

2.2.1. Types of short-circuit 2.2

2.2.2. The peak value of the short-circuit current 2.3

2.2.3. Calculation of the short-circuit current close to the transformer 2.4

2.2.4. Calculation of the short-circuit current in radial supply systems 2.7

2.2.5. Dynamic stress on the connecting leads

in the case of a short-circuit 2.16

2.3. Short-circuit protection 2.18

2.3.1. The principle of current limitation 2.18

2.3.2. Breaking capacity 2.26

2.3.3. Electrical life (durability) of

circuit breakers 2.26

2.4. Short-circuit co-ordination 2.28

2.4.1. Definitions in accordance with

the IEC 947-4-1 2.28

2.4.2. Conclusions drawn from the

definitions for the user 2.28

2.4.3. Physical significance of the short-circuit

co-ordination 2.30

2.4.4. Requirements of a circuit breaker for a simple

co-ordination of type "2" 2.33

3. Fields of application of circuit breakers 3.1

3.1. General procedure for the selection of

correctly rated circuit breakers 3.1

3.2. Circuit breakers for motor protection 3.2

3.2.1. Protection of motors with direct-on-line starting 3.3

3.2.2. Protection of motors with star-delta starting 3.4

3.2.3. Protection during heavy-duty starting 3.8

3.2.4. Circuit breaker with a motor protective

device connected downstream 3.8

3.2.5. Protection of motors in explosive environments 3.12

3.2.6. Protection of motors with phase controlled

starting (soft starter) 3.13

3.2.7. Protection of frequency controlled motors

(frequency converter) 3.14

3.3. Circuit breakers for the protection of

connecting leads and for group protection 3.16

3.3.1. Protection of the connecting leads 3.16

3.3.2. Group protection 3.16

3.4. Circuit breakers for capacitors 3.17

3.5. Circuit breakers for transformers 3.18

3.5.1. Protection of transformer: primary side 3.18

3.5.2. Protection of transformer: secondary side 3.18

3.6. Circuit breakers for generators 3.18

3.7. Circuit breakers for special supply frequencies 3.19

3.7.1. Breaking capacity at frequencies below 50/60Hz 3.19

3.7.2. Breaking capacity at frequencies above 50/60Hz 3.20

3.8. Interruption of direct current 3.20

3.9. Breaking capacity at higher supply voltages 3.21

3.10. Selectivity (discrimination) 3.21

3.10.1. Selectivity between circuit breakers 3.21

3.10.2. Selectivity between circuit breaker and fuse 3.24

3.10.3. Selectivity between fuses 3.25

4. Arguments in favor of the circuit breaker 4.1

4.1. Summary 4.1

4.2. Comparison of the functions:

circuit breaker / fuse 4.2

4.2.1. Time-current characteristics 4.2

4.2.2. Comparison of Joule-integrals 4.3

4.2.3. Comparison of the ultimative tripping current 4.4

4.2.4. Table of comparison 4.4

4.3. Arguments in favour of the circuit breaker 4.6

4.3.1. Prevention of accidents with the help of

circuit breakers 4.6

4.3.2. Ready to be switched on again without delay 4.8

4.3.3. All pole interruption 4.9

4.3.4. No ageing 4.9

4.3.5. Reduction of the conductor cross-section 4.10

4.3.6. Simplified planning of installations 4.14

4.3.7. Reduction of costs of installations and

optional costs 4.14

iii

Circuit

DOWNLOAD EBOOK:

http://literature.rockwellautomation.com/idc/groups/literature/documents/wp/140m-wp001_-en-p.pdf

Tuesday, August 13, 2013

Friday, August 2, 2013

Electrical Panel Board Final Inspection and Testing

Final Inspection and Testing

QCI Carry out ROUTINE TESTS as per IEC 60439-1 standards. The following minimum tests

must be performed:

Visual inspection test – Checking of the complete switchboard in accordance with IEC

60439-1 standards and approved drawings. Checking of Integrity of Wiring, Tightness of all

joints, and Torque test on all bus connections, etc.

Di-electric Test – Done using a MEGGER (verification of Insulation resistances between

phases, phase-neutral, phase-earth and neutral-earth). This test is also verified by a HIPOT

test using a 2.5kV test between phases for 1min.

Mass Continuity Test – To check if there is proper earth continuity from end of the

switchboard to the other. This test can be checked

Thursday, August 1, 2013