Design And Construction Of A 3.5KVA Automatic Inverter Changeover

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Abstract

This work is on change over selector switch for automatic toggling of an inverter when AC mains is present and vice versa and also the system must enable automatic switching of the battery charger such that when AC mains is present the inverter battery gets charged and when AC mains fails, the battery gets connected with the inverter for supplying AC to the load. The configuration should be such that everything takes place automatically and the appliances are never switched OFF, just reverted from inverter AC to Mains AC and vice versa during mains power failures and restorations.

Chapter One

INTRODUCTION
1.1 BACKGROUND OF THE STUDY
This automatic inverter Changeover Switch is a device used to switch off a power supply and subsequently switch on another power supply. Basically it is aimed at switching on a more convenient power supply to the load. This work offers automatic toggling of an inverter when AC mains is present and vice versa and also the system must enable automatic switching of the battery charger such that when AC mains is present the inverter battery gets charged and when AC mains fails, the battery gets connected with the inverter for supplying AC to the load.
Since it switches on power to the load, precautions has to be taken while choosing the type of Change Over Switch, while selecting the appropriate size, the control of arcing has to be put into consideration.
A good switch should be the one whose contact is made in such a way as to limit the arc formation by having no contact-bounce and by having contacts made of good conductive, corrosion resistance and wear resistance materials.
A good change over switch must have adequate insulation and must be so constructed and located as not to constitute a potential hazard.
A good change over switch should also have tight contact points so as to limit or eliminate the possibility of partial contact at the contact point. The partial contact leads to over heating of the components and may lead to fire outbreak in the entire room.

1.2 PROBLEM STATEMENT
In the last decay, switching from mains supply to solar inverter and vice –versa is done manually, and this involves labour, wastes time and at the same time can expose the operator to risk of electric shock. However, this device was invented to solve this problem, it switches automatically between the mains supply and solar inverter when the need arise.

1.3 AIMS AND OBJECTIVES
Due to inconsistent supply of power, there is a growing need for an alternative source of power supply that is the major reason of having inverter. This has lead to heavy capital investment in a bid to suppress power failure and ensure regular power supply for the industry, hospitals, schools and homes. The problem of power failure can be checkmated with the use of stand-by inverter system.
If some of these big firm do not make provisions for stand-by power source, frustration could set in which may lead to the closure of business and thus throwing workers into unemployment. Also in the case of hospital, undergoing a surgical operation and power supply suddenly go off, the patient might loose his or her life due to the power outage.
In view of these considerations, this project is aimed at designing and constructing a workable automatic change over switch for an inverter which offers automatic toggling of an inverter when AC mains is present and vice versa and also the system must enable automatic switching of the battery charger such that when AC mains is present the inverter battery gets charged and when AC mains fails, the battery gets connected with the inverter for supplying AC to the load.

1.4 SIGNIFICANCE OF THE PROJECT
The automatic change over switch, the switch aimed at achieving the following automatic actions;
• To change power over from inverter to mains supply and vice-versa and also to enable automatic switching of the battery charger such that when AC mains is present the inverter battery gets charged and when AC mains fails, the battery gets connected with the inverter for supplying AC to the load.
The automatic change over unit can be operated in single inverter has the following advantages;
It minimizes damages to lives/equipment since it has its own monitoring system and its switching requires no human contact with the switch, thus eliminating human error.
It reduces its change over timing to the minimum due to its fast response to power outage.
It maintains high quality of service through its fast and prompt response.
Moreover, the size and captivity of the unit will depend upon the load for which it will be used. The unit is also portable, easy, convenient and safe to install.

1.5 SCOPE AND LIMITATION OF THE STUDY
This work covers only a one phase automatic changeover which can only be used for providing a means of switching from inverter to AC mains and vice- versa in the case of failure in public utility.

1.6 APPLICATIONS OF THE PROJECT
1. Apart from using this work in inverter, this circuit can also be used as a home lighting system with few modifications.
2. It can be used to drive other DC loads like a DC motor of any electronic appliance or other toy applications.

Table of Contents

COVER PAGE
TITLE PAGE
APPROVAL PAGE
DEDICATION
ACKNOWELDGEMENT
ABSTRACT

CHAPTER ONE
INTRODUCTION
1.1 BACKGROUND OF THE PROJECT
1.2 PROBLEM STATEMENT
1.3 AIMS AND OBJECTIVES
1.4 SIGNIFICANCE OF THE PROJECT
1.5 SCOPE OF THE PROJECT
1.6 APPLICATION OF THE PROJECT
1.7 LIMITATION THE PROJECT
1.8 METHODOLOGY
1.9 PROJECT ORGANISATION

CHAPTER TWO
LITERATURE REVIEW
2.1 DESCRIPTION OF A RELAY
2.2 HISTORY OF POWER FAILURE AND SYSTEM RELIABILITY
2.3 TYPES OF POWER FAILURE
2.4 PROTECTING THE POWER SYSTEM FROM FAILURE
2.5 RESTORING POWER AFTER A WIDE-AREA OUTAGE
2.6 POWER FAILURE INEVITABILITY AND ELECTRIC SUSTAINABILITY
2.7 MITIGATION OF POWER OUTAGE FREQUENCY

CHAPTER THREE
SYSTEM METHODOLOGY
3.1 BLOCK DIAGRAM OF THE SYSTEM
3.2 CIRCUIT DESCRITION AND OPERATION
3.1 SYSTEM CIRCUIT DIAGRAM

CHAPTER FOUR
4.0 TEST AND RESULT ANALYSIS
4.1 CONSTRUCTION PROCEDURE
4.2 ASSEMBLING OF SECTIONS
4.3 TESTING OF SYSTEM OPERATION
4.4 CONSRUCTION OF THE CASING
4.5 ECONOMIC OF THE PROJECT
4.6 PROJECT VIABILITY
4.7 RELIABILITY
4.8 PROJECT EVALUATION
4.9 TESTING, TROUBLESHOOTING AND REMEDY
4.10 TROUBLE SHOOTING AND REMEDY

CHAPTER FIVE
5.1 CONCLUSION
5.2 RECOMMENDATION
REFERENCES