Electrical Machines Tutorial
Selected Reading
- Electrical Machines - Discussion
- Electrical Machines - Resources
- Electrical Machines - Quick Guide
- Power Developed by Synchronous Motor
- Equivalent Circuit and Power Factor of Synchronous Motor
- Working of 3-Phase Synchronous Motor
- Losses and Efficiency of 3-Phase Alternator
- Output Power of 3-Phase Alternator
- Armature Reaction in Synchronous Machines
- Working of 3-Phase Alternator
- Construction of Synchronous Machine
- Introduction to 3-Phase Synchronous Machines
- Methods of Starting 3-Phase Induction Motors
- Speed Regulation and Speed Control
- Characteristics of 3-Phase Induction Motor
- Three-Phase Induction Motor on Load
- Construction of Three-Phase Induction Motor
- Three-Phase Induction Motor
- Single-Phase Induction Motor
- Introduction to Induction Motor
- Applications of DC Machines
- Losses in DC Machines
- Types of DC Motors
- Back EMF in DC Motor
- Working Principle of DC Motor
- Types of DC Generators
- EMF Equation of DC Generator
- Working Principle of DC Generator
- Types of DC Machines
- Construction of DC Machines
- Types of Transformers
- Three-Phase Transformer
- Efficiency of Transformer
- Losses in a Transformer
- Transformer on DC
- Ideal and Practical Transformers
- Turns Ratio and Voltage Transformation Ratio
- EMF Equation of Transformer
- Construction of Transformer
- Electrical Transformer
- Fleming’s Left Hand and Right Hand Rules
- Concept of Induced EMF
- Faraday’s Laws of Electromagnetic Induction
- Rotating Electrical Machines
- Singly-Excited and Doubly Excited Systems
- Energy Stored in a Magnetic Field
- Electromechanical Energy Conversion
- Electrical Machines - Home
Selected Reading
- Who is Who
- Computer Glossary
- HR Interview Questions
- Effective Resume Writing
- Questions and Answers
- UPSC IAS Exams Notes
Construction of Transformer
Construction of Transformer
A transformer consists of three major parts namely a primary winding, a secondary winding and a magnetic core. The primary winding is one that used to input the supply and secondary winding is one that used to take output. The magnetic core is used to confine the magnetic flux to a definite path.
We design a transformer in such a way that it approaches the characteristics of an ideal transformer. In practice, we incorporate the following design features for transformer construction −
The core of the transformer is made up of high grade sipcon steel which has high permeabipty and low hysteresis loss.
The core is laminated to minimize the eddy current loss.
It is a usual and more efficient practice to wind one-half of the primary and secondary windings on one pmb instead of placing primary on one pmb and secondary on the other. This ensures tight magnetic couppng between the two windings and hence reduces the leakage flux considerably.
The winding resistances R1 and R2 are reduced as much as possible so that they cause lowest I2R loss and temperature rise and ensure higher efficiency.
Transformer Construction
A transformer can be constructed in the following two ways −
Core Type Transformer Construction
Shell Type Transformer Construction
Core Type Construction of Transformer
In the core type construction of the transformer, the magnetic core has two vertical lags (called pmbs) and two horizontal sections (called yokes). The half of the primary winding and the half of the secondary winding are placed around each pmb as shown in Figure-1.
This arrangement of windings minimizes the leakage flux. In practice, the low-voltage winding (it could be primary or secondary) is placed next to the core and the high-voltage winding is placed around the low-voltage winding. This considerably reduces the requirement of insulating material.
The main advantage of the core-type construction of transformers is that it is easier to dismantle for repair and maintenance. The core-type construction is most suitable for high-voltage and high-power transformers because in the core type construction, the nature coopng is more efficient.
Shell Type Construction of Transformer
In the shell-type construction of transformers, both primary and secondary windings are wound on the central pmb, while the two outer pmbs complete the low reluctance flux paths as shown in Figure-2.
In this case, each winding is sub-spanided into sections, and the low-voltage (lv) winding sections and high-voltage (hv) winding sections are alternatively put in the form of a sandwich. Therefore, this type of winding is also called as sandwich winding or disc winding.
The shell-type construction of transformers provides better mechanical support against electromagnetic forces between the current-carrying windings. Also, this transformer construction provides a shorter path for magnetic flux and hence requires small magnetizing current. The shell-type construction is more suitable for low voltage transformers because of poor nature coopng due to the embedding of the windings.
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