Showing posts with label arrangement. Show all posts
Showing posts with label arrangement. Show all posts

Wednesday, 1 April 2020

SAG in electrical power transmission.

What is  Sag.?

In electrical power transmission and mechanical design of overhead transmission line.

SAG.

A perfectly flexible wire of uniform cross-section, when string between the two supports at the same level, will form a catenary. However, if the sag is very small compared to the span, its shape approximation a parabola.
 The difference in level between the point of support and the lowest point on the conductor is known as sag 

The factors affecting the sag in an overhead line are given below.

1. Weight of the Conductor,
 This affect the sag directly. Heavier the conductor, greater will be the sag. In locations where ice formation takes place on the conductor, this will also cause increase in the sag.

2. Length Of the Span.
This also affect the sag. Sag is directly proportional to the square of the span length Hence other conditions, such as type of conductor, working tension, temperature etc. remaining the same a section with longer span will have much greater sag.

3. Working Tensile Strength.
The sag is inversely proportional to the working tensile strength of conductor if other conditions such as temperature, length of span remain the same. Working tensile strength of the conductor is determined by multiplying the ultimate stress and area of cross section and dividing by a factor of safety.

4. Temperature.
All metallic bodies expand with the rise in temperature and, therefore. The length of the conductor increases with the rise in temperature, and so does the sag.



Reference from .
Transmission and distribution of electrical power by-J.B.Gupta.
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Sunday, 21 September 2014

TYPES OF BUS BAR SYSTEM

TYPES OF BUS BAR SYSTEM
1 Single Busbar System
Single busbar system is as shown below in figure 

Single Busbar System
a. Merits
1. Low Cost
2. Simple to Operate
3. Simple Protection
b. Demerits
1. Fault of bus or any circuit breaker results in shut down of entire substation.
2. Difficult to do any maintenance.
3. Bus cannot be extended without completely deenergizing substations.
c. Remarks
1. Used for distribution substations up to 33kV.
2. Not used for large substations.
3. Sectionalizing increases flexibility.

2 Main & Transfer Bus bar System
Main & Transfer Bus is as shown below in figure 

a. Merits
1. Low initial & ultimate cost
2. Any breaker can be taken out of service for maintenance.
3. Potential devices may be used on the main bus.
b. Demerits
1. Requires one extra breaker coupler.
2. Switching is somewhat complex when maintaining a breaker.
3. Fault of bus or any circuit breaker results in shutdown of entire substation.
c. Remarks
1. Used for 110kV substations where cost of duplicate bus bar system is not justified. 

3 Double Bus bar Single Breaker system
Double Bus Bar with Double Breaker is as shown below in figure 


a. Merits
1. High flexibility
2. Half of the feeders connected to each bus
b. Demerits
1. Extra bus-coupler circuit breaker necessary.
2. Bus protection scheme may cause loss of substation when it operates.
3. High exposure to bus fault.
4. Line breaker failure takes all circuits connected to the bus out of service.
5. Bus couplers failure takes entire substation out of service.      
c. Remarks
Most widely used for 66kV, 132kv, 220kV and important 11kv, 6.6kV, 3.3kV

Substations.

4 Double Bus bar with Double breaker System
 Double Bus Bar with Double breaker system is as shown below in figure 


a. Merits
1. Each has two associated breakers
2. Has flexibility in permitting feeder circuits to be connected to any bus
3. Any breaker can be taken out of service for maintenance.
4. High reliability
b. Demerits
1. Most expensive
2. Would lose half of the circuits for breaker fault if circuits are not connected to both the buses.
c. Remarks
1. Not used for usual EHV substations due to high cost.

2. Used only for very important, high power, EHV substations.

5 Double Main Bus & Transfer Busbar System
Double main bus & transfer bus system is as shown below in figure


a. Merits
1. Most flexible in operation
2. Highly reliable
3. Breaker failure on bus side breaker removes only one ckt. From service
4. All switching done with breakers
5. Simple operation, no isolator switching required
6. Either main bus can be taken out of service at any time for maintenance.
7. Bus fault does not remove any feeder from the service
b. Demerits
1. High cost due to three buses
c. Remarks

1. Preferred by some utilities for 400kV and 220kV important substations.

6 ONE & HALF BREAKER SCHEME
a. Merits
1. Flexible operation for breaker maintenance.
2. Any breaker can be removed from maintenance without interruption of load.
3. Requires 1 1/2 breaker per feeder.
4. Each circuit fed by two breakers.
5. All switching by breaker.
6. Selective tripping.
b. Demerits
1. One and half breakers per circuit, hence higher cost
2. Any breaker can be removed from maintenance without interruption of load.
c. Remarks
1. Used for 400kV & 220kV substations.
2. Preferred.

7 RING OR MESH ARRANGEMENT

a.      Merits
Bus bars gave some operational flexibility.
b.      Demerits
1. If fault occurs during bus maintenance, ring gets separated into two sections.
2. Auto-reclosing and protection complex.
3. Requires VT’s on all circuits because there is no definite voltage reference point.
4. Breaker failure during fault on one circuit causes loss of additional circuit because of breaker failure.
These VT’s may be required in all cases for synchronizing live line or voltage indication
c.       Remarks
 Most widely used for very large power stations having large no. of incoming and outgoing lines and high power transfer.

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