Skip to main content

Breaker Schemes in Substations

Breaker Schemes in Substations — Types, Design, Advantages, Disadvantages, and Comparison

Author: Engr. Aneel Kumar

Breaker schemes infographic for substations
Figure 1: Infographic overview of breaker schemes commonly used in substations.

Introduction

The breaker scheme or busbar arrangement in a substation defines how incoming feeders, outgoing feeders, and power transformers are connected to the bus. The choice of scheme has a direct impact on system reliability, maintainability, safety, and cost.

A simple bus scheme is economical but vulnerable to outages, while advanced schemes such as breaker-and-a-half or double-bus/double-breaker provide very high reliability but at much higher cost and design complexity.

Engineers select breaker schemes considering fault tolerance, maintenance needs, space requirements, expansion possibilities, protection coordination, and capital investment. Below, we explain each commonly used scheme in detail, along with advantages, disadvantages, and practical applications.

1. Single-Bus Scheme

The single-bus scheme is the simplest arrangement where all circuits (feeders, transformers, incoming lines) are connected to a single busbar through their respective circuit breakers. It is widely used in small substations, rural areas, and low-voltage systems where cost reduction is a primary concern.

In this scheme, a single bus failure results in complete shutdown. Therefore, although economical, it is the least reliable. Still, it is preferred where power supply is non-critical and outages can be tolerated.

Advantages

  • Lowest installation cost and simplest design.
  • Requires minimum equipment (only one breaker per circuit).
  • Easy to operate, simple protection scheme.
  • Compact arrangement, suitable for small substations.
  • Quick commissioning and low maintenance needs.
  • Ideal for temporary or emergency substations.

Disadvantages

  • Very low reliability — any bus or breaker failure interrupts the whole substation.
  • No flexibility during maintenance (complete outage needed).
  • Not suitable for important load centers or industrial systems.
  • Expansion without outage is impossible.
  • Single fault can cause a blackout of all connected feeders.
Related posts:

2. Double-Bus / Double-Breaker Scheme

The double-bus, double-breaker scheme connects each circuit to two buses via two separate breakers. This ensures that if one bus or breaker fails, the circuit remains connected through the other. It is mainly used in critical substations, metropolitan networks, and EHV transmission systems.

This scheme provides maximum reliability and operational flexibility. However, the cost is very high because it requires double the number of breakers, isolators, and busbar arrangements.

Advantages

  • Very high reliability; no single fault causes complete outage.
  • Flexibility to operate circuits from either bus independently.
  • Maintenance of any breaker or bus without service disruption.
  • Suitable for heavily loaded and critical substations.
  • Excellent system security during contingencies.
  • Feeder circuits can be shifted between buses easily.
  • Ensures uninterrupted supply for metropolitan grids.

Disadvantages

  • Highest capital cost of all breaker schemes.
  • Large substation space required.
  • More complex relaying and control schemes.
  • High maintenance cost due to double equipment.
  • Not economical for small or medium substations.
Related posts:

3. Main-and-Transfer Bus Scheme

The main-and-transfer bus scheme includes two buses: the main bus (normally energized) and the transfer or auxiliary bus. A bus coupler connects the two buses, and during maintenance or bus faults, a circuit can be shifted to the transfer bus.

This scheme is more reliable than the single-bus but cheaper than the double-bus/double-breaker arrangement. However, during transfer, circuits may remain unprotected unless backup protection is provided.

Advantages

  • Moderate cost compared to double-bus arrangements.
  • Improves reliability compared to single-bus.
  • Provides flexibility during maintenance of breakers or main bus.
  • Can energize feeders from auxiliary bus when main bus is down.
  • Allows busbar sectionalizing using the coupler breaker.
  • Widely used in medium-voltage substations.

Disadvantages

  • Transfer process is manual and time consuming.
  • During transfer, feeders may be left unprotected.
  • Bus coupler adds extra cost and complexity.
  • Not as reliable as breaker-and-a-half or ring bus schemes.
  • Not suitable for highly critical substations.
Related posts:

4. Breaker-and-a-Half Scheme

The breaker-and-a-half scheme connects two circuits between three breakers, where the middle breaker is shared by both circuits. It is one of the most popular schemes in EHV and UHV substations.

This scheme offers very high reliability and flexibility. Any breaker can be removed for maintenance without interrupting service to both circuits. However, relaying becomes complex because the shared breaker must respond correctly to faults in either circuit.

Advantages

  • High reliability and operational flexibility.
  • Any breaker can be maintained without outage to both circuits.
  • Provides redundancy without needing double the breakers.
  • Ideal for EHV/UHV systems and critical grids.
  • Suitable for integration with advanced protection systems.
  • Well balanced between reliability and cost.

Disadvantages

  • Relaying and protection schemes are complex.
  • 1.5 breakers per circuit — higher cost than single bus or main-transfer bus.
  • Requires skilled operators and advanced protection relays.
  • Occupies more space compared to ring bus.
Related posts:

5. Ring Bus Scheme

In the ring bus scheme, all breakers and circuits are connected in a closed loop, forming a ring. Each circuit is fed from two paths, so even if one breaker is out, the circuit remains energized.

This scheme is reliable and provides high flexibility. However, as the number of circuits increases, the ring becomes difficult to operate and expand. It is best suited for medium-sized substations where reliability is important but breaker-and-a-half is too costly.

Advantages

  • High reliability — no single breaker outage can interrupt the system.
  • Each circuit has two supply paths.
  • Maintenance can be performed without complete outage.
  • Cost is lower than double-bus/double-breaker.
  • Relatively compact arrangement for medium systems.

Disadvantages

  • Protection and relaying complexity increases with more circuits.
  • System expansion is difficult compared to other schemes.
  • Less flexible than breaker-and-a-half for large networks.
  • Not suitable for very high voltage or very large substations.
Related posts:
Single bus, double bus, main and transfer bus arrangements
Breaker-and-a-half and ring bus substation arrangements
Figure 2: Bus and breaker arrangements: (a) Single-bus, (b) Double-bus/double-breaker, (c) Main-and-transfer bus, (d) Breaker-and-a-half, (e) Ring bus.

Comparative Table of Breaker Schemes

Scheme Reliability Flexibility Cost Complexity Space Requirement Maintenance Applications
Single-BusLowVery limitedLowestSimpleSmallEasyRural / small substations
Double-Bus / Double-BreakerVery HighExcellentHighestComplexLargeDifficultCritical metropolitan substations
Main-and-Transfer BusModerateMediumModerateModerateMediumModerateUrban medium substations
Breaker-and-a-HalfHighExcellentHighComplex relayingLargeSkilledEHV/UHV transmission systems
Ring BusHighHighModerateComplexMediumModerateMedium substations
Labels:

Comments

Post a Comment

Popular posts from this blog

PRIMARY SECONDARY AND TERTIARY FREQUENCY CONTROL IN POWER SYSTEMS

Primary, Secondary and Tertiary Frequency Control in Power Systems Author: Engr. Aneel Kumar Keywords: frequency control, primary frequency control, automatic generation control (AGC), tertiary control, load-frequency control, grid stability. Frequency control keeps the power grid stable by balancing generation and load. When generation and demand drift apart, system frequency moves away from its nominal value (50 or 60 Hz). Grids rely on three hierarchical control layers — Primary , Secondary (AGC), and Tertiary — to arrest frequency deviation, restore the set-point and optimize generation dispatch. Related: Power System Stability — causes & mitigation Overview of primary, secondary and tertiary frequency control in power systems. ⚡ Primary Frequency Control (Droop Control) Primary control is a fast, local response implemented by generator governors (dro...
2 comments
Read more

ADVANTAGES AND DISADVANTAGES OF CORONA EFFECT IN TRANSMISSION LINES | ELECTRICAL ENGINEERING GUIDE

Advantages and Disadvantages of Corona Effect in Power Systems In high-voltage overhead transmission lines , the corona effect plays a critical role in system performance. Corona occurs when the air around a conductor becomes ionized due to high electric stress. While often seen as a drawback because of power losses and interference , it also provides certain engineering benefits . This article explains the advantages and disadvantages of corona effect in detail, with examples relevant to modern electrical power systems. ✅ Advantages of Corona Effect Increase in Virtual Conductor Diameter Due to corona formation, the surrounding air becomes partially conductive, increasing the virtual diameter of the conductor. This reduces electrostatic stress between conductors and minimizes insulation breakdown risks. Related Reading: Electrostatic Fields in High Voltage Engineering Reduction of Transient Surges Corona acts like a natural cushion for sudden ...
Read more

CASCADED TRANSFORMERS METHOD FOR GENERATING AC HIGH VOLTAGE

High-Frequency AC High Voltage Generation Using Cascaded Transformers Author: Engr. Aneel Kumar Figure 1: Infographic representation of cascaded transformers method for generating high AC voltages. Introduction In high voltage engineering , generating very high alternating current (AC) voltages is essential for testing equipment like insulators, circuit breakers, power cables, and other apparatus. One common and effective method for producing such voltages is the cascaded transformers method . This technique uses a series connection of specially designed test transformers , where the secondary of one transformer feeds the primary of the next. In this way, voltages are built up step by step, achieving levels in the range of hundreds of kilovolts (kV) or even megavolts (MV). Working Principle The principle of cascaded connection relies on the fact that each...
Read more

Advantages of Per Unit System in Power System Analysis | Electrical Engineering

  Advantages of Per Unit System in Power System Analysis In electrical power engineering, the per unit (p.u.) system is one of the most widely used techniques for analyzing and modeling power systems. It is a method of expressing electrical quantities — such as voltage, current, power, and impedance — as fractions of chosen base values rather than their actual numerical magnitudes. This normalization technique provides a universal language for system calculations, minimizing errors, simplifying transformer modeling, and enabling consistency across multiple voltage levels. Because of these benefits, the per unit system is essential in fault analysis, load flow studies, transformer testing, and short-circuit calculations . ⚡ What is the Per Unit System? The per unit system is defined as: Q u a n t i t y ( p u ) = A c t u a l   V a l u e B a s e   V a l u e Quantity_{(pu)} = \dfrac{Actual \ Value}{Base \ Value} Q u an t i t y ( p u ) ​ = B a se   ...
6 comments
Read more

SYMMETRICAL COMPONENT ANALYSIS

Unbalanced three phase systems can be split into three balanced components, namely Positive Sequence (balanced and having the same phase sequence as the unbalanced supply), Negative Sequence (balanced and having the opposite phase sequence to the unbalanced supply) and Zero Sequence (balanced but having the same phase and hence no phase sequence). These are known as the Symmetrical Components or the Sequence Components and are shown in figure 2.10. The phase components are the addition of the symmetrical components and can be written as follows.  a = a 1 + a 2 + a 0 b = b 1 + b 2 + b 0 c = c 1 + c 2 + c 0 The unknown unbalanced system has three unknown magnitudes and three unknown angles with respect to the reference direction. Similarly, the combination of the 3 sequence components will also have three unknown magnitudes and three unknown angles with respect to the reference direction. Thus the original unbalanced system effectively has 3 complex unknown quan...
Post a Comment
Read more

Comprehensive Guide to Static Var Compensators (SVC): Mechanisms, Configurations, and Applications

  Introduction In modern power systems, voltage stability and reactive power management are critical for ensuring efficient and reliable operation. Static Var Compensators (SVCs), a key component of Flexible AC Transmission Systems (FACTS), address these challenges by dynamically controlling reactive power in AC transmission networks. This article explores SVCs in-depth, including their mechanisms, configurations, applications, and impact on power systems. Keywords: Static Var Compensator Applications, SVC Voltage Regulation Systems, Reactive Power Management Solutions, Harmonic-Free Power Systems, Dynamic Voltage Stabilization Technologies. Understanding Static Var Compensators (SVC) What is an SVC? A Static Var Compensator is a shunt-connected device used to regulate voltage by controlling reactive power in AC systems. Unlike traditional solutions like synchronous condensers, SVCs leverage power electronics for faster and more precise responses to voltage fluctuations. How SVC Wo...
Post a Comment
Read more