Friday, 26 June 2015

Electrical Circuit Breaker Operation and Types of Circuit Breaker

What is Circuit Breaker?


                Definition of circuit breaker: - Electrical circuit breaker is a switching device which can be operated manually as well as automatically for controlling and protection of electrical power system respectively. As the modern power system deals with huge currents, the special attention should be given during designing of circuit breaker to safe interruption of arc produced during the operation of circuit breaker. This was the basic definition of circuit breaker.


Introduction to Circuit Breaker

           
        The modern power system deals with huge power network and huge numbers of associated electrical equipment. During short circuit fault or any other types of electrical fault these equipment as well as the power network suffer a high stress of fault  current  in them which may damage the equipment and networks permanently. For saving these equipment and the power networks the fault current should be cleared from the system as quickly as possible. Again after the fault is cleared, the system must come to its normal working condition as soon as possible for supplying reliable quality power to the receiving ends. In addition to that for proper controlling of power system, different switching operations are required to be performed. So for timely disconnecting and reconnecting different parts of power system network for protection and control, there must be some special type of switching devices which can be operated safely under huge  current  carrying condition. During interruption of huge current, there would be large arcing in between switching contacts, so care should be taken to quench these arcs in circuit breaker in safe manner. The circuit breaker is the special device which does all the required switching operations during  current  carrying condition. This was the basic introduction to circuit breaker.

Working Principle of Circuit Breaker: ( सर्किट ब्रेकर का कार्यकारी नियम)                        

        The circuit breaker mainly consists of fixed contacts and moving contacts. In normal "on" condition of circuit breaker, these two contacts are physically connected to each other due to applied mechanical pressure on the moving contacts. There is an arrangement stored potential energy in the operating mechanism of circuit breaker which is realized if switching signal given to the breaker. The potential energy can be stored in the circuit breaker by different ways like by deforming metal spring, by compressed air, or by hydraulic pressure. But whatever the source of potential energy, it must be released during operation. Release of potential energy makes sliding of the moving contact at extremely fast manner. All circuit breaker have operating coils (tripping coils and close coil), whenever these coils are energized by switching pulse, the plunger inside them  displaced. This operating coil plunger is typically attached to the operating mechanism of circuit breaker, as a result the mechanically stored potential energy in the breaker mechanism is released in forms of kinetic energy, which makes the moving contact to move as these moving contacts mechanically attached through a gear lever arrangement with the operating mechanism. After a cycle of operation of circuit breaker the total stored energy is released and hence the potential energy again stored in the operating mechanism of circuit breaker by means of spring charging motor or air compressor or by any other means. Till now we have discussed about mechanical working principle of circuit breaker. But there are electrical characteristics of a circuit breaker which also should be considered in this discussion of operation of circuit breaker.


Discussion on electrical principle of circuit breaker.


                  The circuit breaker has to carry large rated or fault power. Due to this large power there is always dangerously high arcing between moving contacts and fixed contact during operation of circuit breaker. Again as we discussed earlier the arc in circuit breaker can be quenching safely if the dielectric strength between the current carrying contacts of circuit breaker increases rapidly during every current zero crossing of the alternating current. The dielectric strength of the media in between contacts can be increased in numbers of ways, like by compressing the ionized arcing media since compressing accelerates the deionization process of the media, by cooling the arcing media since cooling increase the resistance of arcing path or by replacing the ionized arcing media by fresh gasses. Hence a numbers of arc quenching processes should be involved in operation of circuit breaker. 


Types of Circuit Breaker (सर्किट ब्रेकर के प्रकार )


According different criteria there are different types of circuit breaker.

 According to their arc quenching media the circuit breaker can be divided as-
Oil circuit breaker.
Air circuit breaker.
SF6 circuit breaker.
Vacuum circuit breaker.

 According to their services the circuit breaker can be divided as-
Outdoor circuit breaker
Indoor breaker.

According to the operating mechanism of circuit breaker they can be divided as-
Spring operated circuit breaker.
Pneumatic circuit breaker.
Hydraulic circuit breaker.

According to the voltage level of installation types of circuit breaker are referred as-
High voltage circuit breaker.
Medium voltage circuit breaker.
Low voltage circuit breaker.



Feedbacks From Readers Are Most Welcomes.....in comment section


Blogger Widget

Saturday, 6 June 2015

8 Major Advantages of Distribution Automation



8 Major Advantages of Distribution Automation
________________________________________________________________________________________________________


Economic Challenges
More and more electric utilities are looking to distribution automation as an answer to the three main economic challenges facing the industry:
  1. The rising cost of adding generating capacity,
  2. Increased saturation of existing distribution networks and
  3. Greater sensitivity to customer service.[/info_box]
Therefore, utilities that employ distribution automation expect both cost and service benefits.
These benefits accumulate in areas that are related to investments, interruptions and customer service, as well as in areas related to operational cost savings, as given below:

1. Reduced line loss
The distribution substation is the electrical hub for the distribution network.
A close coordination between the substation equipment, distribution feeders and associated equipment is necessary to increase system reliability. Volt/VAR control is addressed through expert algorithms which monitors and controls substation voltage devices in coordination with down-line voltage devices to reduce line loss and increase line throughout.

2. Power quality
Mitigation equipment is essential to maintain power quality over distribution feeders.
The substation RTU in conjunction with power monitoring equipment on the feeders monitors, detects, and corrects power-related problems before they occur, providing a greater level of customer satisfaction.

3. Deferred capital expenses
A preventive maintenance algorithm may be integrated into the system. The resulting ability to schedule maintenance, reduces labour costs, optimizes equipment use and extends equipment life.

4. Energy cost reduction
Real-time monitoring of power usage throughout the distribution feeder provides data allowing the end user to track his energy consumption patterns, allocate usage and assign accountability to first line supervisors and daily operating personnel to reduce overall costs.

5. Optimal energy use
Real-time control, as part of a fully-integrated, automated power management system, provides the ability to perform calculations to reduce demand charges.
It also offers a load-shedding / preservation algorithm to optimize utility and multiple power sources, integrating cost of power into the algorithm.

6. Economic benefits
Investment related benefits of distribution automation came from a more effective use of the system. Utilities are able to operate closer to the edge to the physical limits of their systems. Distribution automation makes this possible by providing increased availability of better data for planning, engineering and maintenance.
Investment related benefits can be achieved by deferring addition of generation capacity, releasing transmission capacity and deferring the addition, replacement of distribution substation equipment. Features such as voltage/VAR control, data monitoring and logging and load management contribute to capital deferred benefits.
Distribution automation can provide a balance of both quantitative and qualitative benefits in the areas of interruption and customer service by automatically locating feeder faults, decreasing the time required to restore service to unfaulted feeder sections, and reducing costs associated with customer complaints.

7. Improved reliability
On the qualitative side, improved reliability adds perceived value for customer and reduce the number of complaints. Distribution automation features that provide interruption and customer service related benefits include load shedding and other automatic control functions.
Lower operating costs are another major benefits of distribution automation.
Operating cost reduction are achieved through improved voltage profiles, controlled VAR flow, repairs and maintenance savings, generation fuel savings from reduced substation transformer load losses, reduced feeder primary and distribution transformer losses, load management and reduced spinning reserve requirements.
In addition, data acquisition and processing and remote metering functions play a large role in reducing operating costs and should be considered an integral part of any distribution automation system. Through real time operation, the control computer can locate the faults much faster and control the switches and reclosures to quickly reroute power and minimize the total time-out, thus increasing the system reliability.

8. Compatibility
Distribution automation spans many functional and product areas including computer systems, application software, RTUs, communication systems and metering products. No single vendor provides all the pieces. Therefore, in order to be able to supply a utility with a complete and integrated system, it is important for the supplier to have alliances and agreements with other vendors.
An effective distribution automation system combines complementary function and capabilities and require an architecture that is flexible or “opens” so that it can accommodate products from different vendors.
In addition, a distribution automation system often requires interfaces with existing system in order to allow migration and integration, still monitoring network security.
Blogger Widget