CONSTRUCTION OF A TWO FACE GAS BURNER

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CONSTRUCTION OF A TWO FACE GAS BURNER

ABSTRACT

          This project which is on the design and fabrication of a two face gas burner is a brief exploration on the various ways and means of designing, construction, operating the two face gas burner, putting cost into consideration for economic advantage.  Herein are brief information and literature on gas burner.  The properties of the constructional feature and their preference in construction are described.  The combustion reaction resulting to the heat liberated is also given.  Also, the practical approach in making the construction of a two face gas burner up to this standard is also given and recommendation to improve on the standard is also included in this report.

TABLE OF CONTENTS

CHAPTER ONE

1.1           Introduction

1.2           Literature review

1.3           Specification of problem

1.4           Component parts and their functions

CHAPTER TWO

CONSTRUCTION MECHANISM / THEORY OF COMBUSTION

2.1           Description of combustion devices

2.2           Pre mix or nozzle air blast burner

2.3           Mode of operation

2.4           Flame

2.5           Ultimate analysis

2.6           Requirement of the gas

CHAPTER THREE

MATERIAL SELECTION

3.1           Properties

3.2           Mid steel

3.3           Brass

3.4           Cast iron

3.5           Hose

3.6           Copper pipe

CHAPTER FOUR

CONSTRUCTION PROCEDURE

4.1           Tools and equipment used

4.2           Sequence of manufacturing

CHAPTER FIVE

ASSEMBLY OF THE PROJECT

5.1           Front view

5.2           Plan

5.3           Side view

CHAPTER SIX

COST OF PRODCUTION/COST ANALYSIS

6.1           Design cost

6.2           Material cost

6.3           Machine cost

6.4           Total cost

CHAPTER SEVEN

MAINTENANCE OF DEVICE

7.1           Safety precautions

7.2           Testing of the device

7.3           Recommendation

7.4           Conclusion

7.5           References

CHAPTER ONE

1.1           INTRODUCTION

The construction of a two-face gas burner as a project topic that we embark upon become necessary as a way of way of putting into application the engineering and technological knowledge acquired so far. It is a starting point of actualizing a functional technology in the country. Irrespective of the fact that there are several breads of gas burners in the market, especially the ones imported, we deemed it necessary to work further on it as a way of modifying the brand with cast not left out in such modification.  

1.2    LITERATURE REVIEW

          The development of simple gas burner started in the eighteen countries when people began to use coal gas for burning. The application was fast put into practice by William Mulock who designed the simple gas cooker to be used in his office, home and workplace

          The first experimental gas cooker was made and in use in 1850. The improvement of this has multiplied greatly and is up to date widely used in homes, restaurants and large catering establishments. The different types of gas cookers available in the in the market are based on skills and techniques of the designer or producer.

          Based on the nature of energy supply, some gas cookers are made up of combustion devices of an electric heating element. The well-constructed ones are properly adapted and form an integral combustion of which of which they generate and utilize heat. It is often quite different to draw a line where heat generation stops and where heat utilization starts in a fuel forced cooker. That is the fuel fired cooker being on the pack in the market these days.

          The releasing of heart starts with mixture of air and fuel gas in the nozzle and combustion of the mixture to release heart takes place at the burner.

1.3    SPECIFICATION OF PROBLEM

          In the course of fabricating the two-face gas burner, as a copied project with some propose modification, some condition which ought to be met are found as a standard of comparison with the already existing ones. This posed a difficulty in the course of this construction. Since choice between already existing gas cooker lies on service available, durability, connivance cost.

          The following specifications were considered a problem when we started the design.

1.    PORTABILITY.

How to fabricate a two-face gas burner that will occupy the minimum space in the kitchen was a problem. A two-face gas burner that is easily to be met in met in our design.

2.                To construct a two-face gas burner that will be safe to any prospective user.

3.                To constructs a two-face gas burner that will be easy to maintain and wise gas will be free from unpleasant smell.

4.                To construct a two-face gas burner whose source of energy (fuel) will be local.

1.4           COMPONENT PARTS AND THEIR FUNCTIONS

1.                Burner chamber

2.                Linkage pipe

3.                Hose

4.                Gas Cylinder (containing gas valve)

5.                Angle bar (material)

6.                Control knob or valve

7.                Connection pipe for gas flow

8.                Nut

9.                Rod.

THE BURNER: This being the main component where combustion takes place to release heat. There is gas delivery line, which leads to it in addition to an adjustment to control the rate of atmospheric air mixing with the natural gas

 

                                                                            

LINKAGE PILE:       This is the pipe line through which natural gas flow to the burner. One is lined along the frame of the burner as seen. 

 

THE GAS CYLINDER:     This is the component of the gas burner that containing the gas fuel through which a hose as connected to the copper pipe of the burner through the gas passes to the burner for combustion.

 

THE ANGLE BAR:   This was used in constructing the frame of the gas burner.

HOSE:      This serves as a link between the copper tubing and the control value of the burner.

 

CONTROL KNOB OR VALVE:         It is a essential component of the gas burner and it is used to regulate the volume or amount of natural gas flowing to the burner.

 

MILD STELL PLATE       this is used as a covering or a wall for the gas burner. It also serves as a seat for the values.

 

CHAPTER TWO

COMBUSTION MECHANISM/THEORY OF THE GAS BURNER

2.1           DESCRIPTION OF COMBUSTION DEVICE.

There are different types of commercially fixed gas burner and combustion equipment in which usage. Some knowledge of this type of burner, combustion and aerodynamics within a plant is therefore essential if a physical study is to be a success.

The combustion equipment is usually selected to satisfy a range of design requirement including firmly rate, flame length and shape, temperature and combustion product. All these factors influence the heat transfer, hence the thermal efficiency of the burner in a particular and on the nature on its aerodynamics behaviour when installed in plant.

In practice, many burner fall into categories which has deterring implication

2.2    PRE-MIX OR NOZZLE AIR BAST BURNER

          In both cases, flame stabilization is commonly achieved by employing a refractory tunnel downstream at the burner head with combustion substantially completed within the tunnel. This produces a high velocity stream of combustion product as close to adiabatic flame temperature.

          The velocity and momentum of the jet is often employed to promote high rate of recitations of combustion of the burner. When mixing is an good proportion, there will be complete, occupying a fraction of the combustion chamber.

          Direct radiation from the flame to the load is small compared to the overall radiant transferred from the hot combustion product flowing within the furnace chamber.

2.3           MODE OF OPERATION

To permit flow of the gas to the pipe loading to the burner, the top or the regulator is turned to “on” position, the  ripple is adjusted to regulate the flow of the gas which also controls the flame size and heat

          The gas then mixes with the air which then flows to the main tunnel. The match is ignited and bought near the small hole where the mixture flows out. A combustion, which gives out a flame, is seen. The nature of the flame depends on the amount air mixing with the fuel gas.

2.4           FLAME

Two type of flame are always observed namely:

1.      THE LUMINOUS FLAME: This is produce when the adjustment completely closes off air to the pipe. The flame will be yellow and when the air is cold it will be smoky. This shows incomplete combustion.

2.      HON LUMNOUS FLAME: This has a blue colour. Its temperature is higher than the luminous flame. It is produced when air is made to flow along the pipe. There is complete combustion.

         

2.5           ULTMATE ANAYSIS OF THE FUEL GAS

The fuel gas used in this project is methane with ultimate analysis of carbon =12g by mass of the total mass.

Hydrogen = 4g by the total mass.

Methane (GH₄) =16g total mass.

Methane constitutes 92.6% by volume of a typical natural gas.

Combustion reaction for complete combustion

CH_4(g) +20^2(g)         C₀₂ + 2H0(g)

Combustion reaction for incomplete combustion

CH_4(g) + ²/3 0_2(g)              C_O(G)  +2H₂⁰_(g).

2.6 REQUIREMENT FOR GAS FUEL

1)                  it must attain a controllable uniform temperature in the burner.

2)                  The fuel mixture should be that which support combustion.

3)                    The fuel mixture should be the type that will react with the materials

the major fuel to be used is methane the simplest compound in the alkene series. It support combustion.

CHAPTER THREE

3.1           MATERIAL SELECTION

As a mandatory step in engineering design, before a material is selected, the general. Properties of such material, its manufacturing process, its chemicals composition has to be considered. In addition, the treatment it receives before  usage need to be considered. This will help to assess the prosperities and quality expected in the design.

In the course  of this project many engineering materials were open to us for a choice to be made. In all these, we looked for some properties before selecting

The properties are as follows

1)               Casting ability.

2)               Toughness of the material

3)               Malleability of the material

4)               Machinability of the material

5)               Ability of the material to withstand considerable heat (surface hardening).

6)               Durability of the material

7)               Ability to withstand indentation

8)               Availability of the material.

9)               Cost of the material

10)          Other properties including rigidity

Weight etc. with above the mind, a lot of engineering materials were considered fit  of these material/alloy that come into mind include galvanized steel, stainless steel, alloyed nickel, iron alloyed aluminum, Brass alloy, mid steel.

          Inspite of several alternatives, our final choice was based on cost with certain properties considered.

3.2           MILD STEEL

This is highly favored in the construction of the body of the gas burner. It posses in addition to the above properties, ability to withstand scratching, abrasion, indentation by harder  body. It can also be easily wielded.

3.3           BRASS

This used in the construction of the valve of the gas burner and tap because of its ductility and strength of its alloy.

3.4           CAST IRON

This is used in the construction of the burner. it has the ability to withstand heat.

3.5           HOSE

This is chose because of its availability and cost effectiveness.

3.6           COPPER PIPE

This is chosen because of its ductility for the construction of the flow channel of fluid. It is flexible, easily straightened to be in line with the frame of the gas burner.

                                                                            

CHAPTER FOUR

CONSTRUCTION PROCEDURE

4.1    The tools and equipment used in the construction of the two face gas burner are

1.      HAND SCRIBER: this was used in marking out the work piece

2.      MEASURING Tape: this was used to measure out the dimensions required of the design.

3.      VICE: this was used to clamp the work piece.

5.    HACK SAW: This was used in cutting the cook piece to the required size.

6.    Try square: this was used to check the squareness of the work piece.

7.    Electric’s are welding machine: this was used in welding the metal parts together.

8.    Drilling  machine: it was used for drilling holes for bolt and nut  

4.2          SEQUENCE OF OPERATION

OPERATION	EQUIPMENT USED	BRIEF DESCRIPTION	SKETCH	TIME
1)   Measuring	Measuring tape	After the material has been bought from the market, a tape calubrated in mm was used to measure out all the component parts required.
2)   Marking out	Hand scriber	Marking out of the measured parts was done with scriber held in hand like a pen.		30 mins
3)   cutting	Hack saw, file, try-square are and vice	Hack saw was used in cutting the angle bars, flat bars, which were clamped to the bench vice while cutting a try square was used to check the square-ness. The cutting was done slightly more than the actual dimension. File was later used to reduce it to its   actual dimension.		1 hour
4)   welding	Try square, welding electrode, Arc welding machine, Angle grander.	The squareness of the parts to be welded were checked with the try square. Frostily welding was done with lower amperage of 80 –100. Finally welding was done with 120-150 amperage so that it will have enough welding deposit. The surface of the work was smoothening with angle grander.
5)   Assembly of burner to frame of the gas  cooker	Welding electrode, Arc welding machine	The burner was set to be at the centre of each frame. It was then welded to the body of the frame.		2 hour
6)   Gas pipe assembly		The gas pipe was given three marks at different places and three sizes of the pipe were used. One was welded with the seating of the burner, the other ones were fixed into the pipe gas   line. It has nut, which holds it together. The last pipe was fitted to the body of the gas cooker. The two gas values were used.
7)   Drilling	Drilling machine	The holes through which the nut were fixed was drilled in the drilling machine and also the burner.		3 hour
8)   smoothening	Emery cloth	The body of the gas cooker frame and pipe were smoothened using emery cloth		1 hour
9)   painting	Painting brush and paint spraying machine	The body of the gas cooker was painted to prevent rusting. Ie  both the frame and the pipes		2 hour

                            

  

CHAPTER FIVE

ASSEMBLY OF THE PROJECT

5.1    FRONT VIEW

                                

CHAPTER SIX

COST OF PRODUCTION AND COST ANALYSIS

This deals with the total cost of accomplishing the project as seen below.

S/NO	MATERIAL	SPECIFICATION	COST(N)
1	Angle bar	18 feet (5485.4.mm)	800.00
2	Mild steel plate	10 feet (3048mm)	800.00
3	Rod (y25)	7 feet (2133.6mm)	300.00
4	Values (gas)		300.00
5	Electrode	3.2mm diameter	250.00
6	Paint	1 tin	800.00
7	Bolt	M6	80.00
8	Sand/Emery cloth		50.00
9	Copper tubing	12.25mm diameter	150.00
10	Hose	12.25mm	100.00
11	Cast iron burner		1000.00
12	Gas cylinder		3000.00

MACHINE COST

S/N	MACHINE	COST(N)
1	Cost of  hiring drilling machine	100.00
2	Cost of hiring oxyacetylene and arc welding machine	500.00
3	Cost of hiring hack-saw blade	100.00
4	Cost of hiring vice	100.00
5	Cost of hiring files	200.00
	TOTAL	1,000.00

Cost of transportation N1500.00

Therefore total cost for completing the project.

Material cost +machine cost + transportation = N10, 130.                 

CHAPTER SEVEN

MAINTENANCE OF THE DEVICE

          To ensure optimum life span of the device, it ought to be properly handled. The operation technique is very import i.e “on” and “off” whenever there is any deficit in the supply of the gas to the burner, the valve and cylinder content should be checked. The cylinder should be refilled if need be. 

          The burner should be cleaned by removing dirt’s, which sticks to it after each use. The valve should be removed and cleaned thoroughly when never low working condition id perceived, after which it should be fixed back.

          A pointed object like pin should be used to remove dirt from the nipple hole. If after the service, the valve still malfunctions, it should be replaced with new one.

7.1           SAFETY PRECAUTION

To safeguard the user and the device against injury and damage respectively, the following precaution should be noted.

1.)             Always lock the cylinder regulator and gas cooker valve after usage.

2.)             Gas leakage should always be checked, as this could lead to poisoning and explosion

3.)             The gas cooker should not be put on without a flame

4.)             It should be used in a well – aerated environment.

5.)             Water should not be used in putting off the flame

6.)             Children should be well instructed on how to operate the device one cannot automatically stop them from using it

7.2           TESTING OF THE DEVICE

After concluding the project the gas cooker was tested in the same shop with gad filled cylinder and it was observed. There was a non luminous (blue) flame and the gas was coming out almost simultaneously. The cooker can only produce a blue (non-luminous) flame if the oxygen flowing inside the burner is properly regulated.

7.3           RECONMENDATION

Since final year project is mandatory to all final year irrespective of the department, we wish to make the following  recommendations that the department should always inform the school authority to always make fund available for projects do that students can finish their final year project without difficulties.  That department should find the importation of new books and technological magazine into the department library n current basis.  This will change students into research and creativity.  That final year topic should be released as early as possible so that students can have time to make exhaustive research.

7.4    CONCLUSION

          Having completed the project, we came to realize that the task of collecting facts and data is influenced by wide range of factors such as time practical application of engineering knowledge in construction.

          This project has really directed our attention to research study and practical engineering application of the knowledge acquired so far.

          With this construction, our hearts and focus is aroused towards actualizing Nigeria dream of building a functional technology.

REFERENCES

EASTOP T.D. AND MCCONKEY .A.           Applied Thermodynamics 5^th Edition 1999

SMITH E.G.M                      Basic Fabrication and welding

Engineering.  Craft Studies

Series Merdyn Hinghes

London Longman 1975.

HUNNNAH J. AND M.J. HILWER                 Applied

Mechanics 2^nd Edition

TOWNSEND A.L                 Plumbing and Gas

Installation 3^rd Edition 1970.

TRINKS .W. AND HAWANNER .M.H.                  Capacity of

Gas 4^th Edition, Industrial

Furnace (1925 – 1967)

CONSTRUCTION OF A TWO FACE GAS BURNER

ABSTRACT

          This project which is on the design and fabrication of a two face gas burner is a brief exploration on the various ways and means of designing, construction, operating the two face gas burner, putting cost into consideration for economic advantage.  Herein are brief information and literature on gas burner.  The properties of the constructional feature and their preference in construction are described.  The combustion reaction resulting to the heat liberated is also given.  Also, the practical approach in making the construction of a two face gas burner up to this standard is also given and recommendation to improve on the standard is also included in this report.

TABLE OF CONTENTS

CHAPTER ONE

1.1           Introduction

1.2           Literature review

1.3           Specification of problem

1.4           Component parts and their functions

CHAPTER TWO

CONSTRUCTION MECHANISM / THEORY OF COMBUSTION

2.1           Description of combustion devices

2.2           Pre mix or nozzle air blast burner

2.3           Mode of operation

2.4           Flame

2.5           Ultimate analysis

2.6           Requirement of the gas

CHAPTER THREE

MATERIAL SELECTION

3.1           Properties

3.2           Mid steel

3.3           Brass

3.4           Cast iron

3.5           Hose

3.6           Copper pipe

CHAPTER FOUR

CONSTRUCTION PROCEDURE

4.1           Tools and equipment used

4.2           Sequence of manufacturing

CHAPTER FIVE

ASSEMBLY OF THE PROJECT

5.1           Front view

5.2           Plan

5.3           Side view

CHAPTER SIX

COST OF PRODCUTION/COST ANALYSIS

6.1           Design cost

6.2           Material cost

6.3           Machine cost

6.4           Total cost

CHAPTER SEVEN

MAINTENANCE OF DEVICE

7.1           Safety precautions

7.2           Testing of the device

7.3           Recommendation

7.4           Conclusion

7.5           References

CHAPTER ONE

1.1           INTRODUCTION

The construction of a two-face gas burner as a project topic that we embark upon become necessary as a way of way of putting into application the engineering and technological knowledge acquired so far. It is a starting point of actualizing a functional technology in the country. Irrespective of the fact that there are several breads of gas burners in the market, especially the ones imported, we deemed it necessary to work further on it as a way of modifying the brand with cast not left out in such modification.  

1.2    LITERATURE REVIEW

          The development of simple gas burner started in the eighteen countries when people began to use coal gas for burning. The application was fast put into practice by William Mulock who designed the simple gas cooker to be used in his office, home and workplace

          The first experimental gas cooker was made and in use in 1850. The improvement of this has multiplied greatly and is up to date widely used in homes, restaurants and large catering establishments. The different types of gas cookers available in the in the market are based on skills and techniques of the designer or producer.

          Based on the nature of energy supply, some gas cookers are made up of combustion devices of an electric heating element. The well-constructed ones are properly adapted and form an integral combustion of which of which they generate and utilize heat. It is often quite different to draw a line where heat generation stops and where heat utilization starts in a fuel forced cooker. That is the fuel fired cooker being on the pack in the market these days.

          The releasing of heart starts with mixture of air and fuel gas in the nozzle and combustion of the mixture to release heart takes place at the burner.

1.3    SPECIFICATION OF PROBLEM

          In the course of fabricating the two-face gas burner, as a copied project with some propose modification, some condition which ought to be met are found as a standard of comparison with the already existing ones. This posed a difficulty in the course of this construction. Since choice between already existing gas cooker lies on service available, durability, connivance cost.

          The following specifications were considered a problem when we started the design.

1.    PORTABILITY.

How to fabricate a two-face gas burner that will occupy the minimum space in the kitchen was a problem. A two-face gas burner that is easily to be met in met in our design.

2.                To construct a two-face gas burner that will be safe to any prospective user.

3.                To constructs a two-face gas burner that will be easy to maintain and wise gas will be free from unpleasant smell.

4.                To construct a two-face gas burner whose source of energy (fuel) will be local.

1.4           COMPONENT PARTS AND THEIR FUNCTIONS

1.                Burner chamber

2.                Linkage pipe

3.                Hose

4.                Gas Cylinder (containing gas valve)

5.                Angle bar (material)

6.                Control knob or valve

7.                Connection pipe for gas flow

8.                Nut

9.                Rod.

THE BURNER: This being the main component where combustion takes place to release heat. There is gas delivery line, which leads to it in addition to an adjustment to control the rate of atmospheric air mixing with the natural gas

 

                                                                            

LINKAGE PILE:       This is the pipe line through which natural gas flow to the burner. One is lined along the frame of the burner as seen. 

 

THE GAS CYLINDER:     This is the component of the gas burner that containing the gas fuel through which a hose as connected to the copper pipe of the burner through the gas passes to the burner for combustion.

 

THE ANGLE BAR:   This was used in constructing the frame of the gas burner.

HOSE:      This serves as a link between the copper tubing and the control value of the burner.

 

CONTROL KNOB OR VALVE:         It is a essential component of the gas burner and it is used to regulate the volume or amount of natural gas flowing to the burner.

 

MILD STELL PLATE       this is used as a covering or a wall for the gas burner. It also serves as a seat for the values.

 

CHAPTER TWO

COMBUSTION MECHANISM/THEORY OF THE GAS BURNER

2.1           DESCRIPTION OF COMBUSTION DEVICE.

There are different types of commercially fixed gas burner and combustion equipment in which usage. Some knowledge of this type of burner, combustion and aerodynamics within a plant is therefore essential if a physical study is to be a success.

The combustion equipment is usually selected to satisfy a range of design requirement including firmly rate, flame length and shape, temperature and combustion product. All these factors influence the heat transfer, hence the thermal efficiency of the burner in a particular and on the nature on its aerodynamics behaviour when installed in plant.

In practice, many burner fall into categories which has deterring implication

2.2    PRE-MIX OR NOZZLE AIR BAST BURNER

          In both cases, flame stabilization is commonly achieved by employing a refractory tunnel downstream at the burner head with combustion substantially completed within the tunnel. This produces a high velocity stream of combustion product as close to adiabatic flame temperature.

          The velocity and momentum of the jet is often employed to promote high rate of recitations of combustion of the burner. When mixing is an good proportion, there will be complete, occupying a fraction of the combustion chamber.

          Direct radiation from the flame to the load is small compared to the overall radiant transferred from the hot combustion product flowing within the furnace chamber.

2.3           MODE OF OPERATION

To permit flow of the gas to the pipe loading to the burner, the top or the regulator is turned to “on” position, the  ripple is adjusted to regulate the flow of the gas which also controls the flame size and heat

          The gas then mixes with the air which then flows to the main tunnel. The match is ignited and bought near the small hole where the mixture flows out. A combustion, which gives out a flame, is seen. The nature of the flame depends on the amount air mixing with the fuel gas.

2.4           FLAME

Two type of flame are always observed namely:

1.      THE LUMINOUS FLAME: This is produce when the adjustment completely closes off air to the pipe. The flame will be yellow and when the air is cold it will be smoky. This shows incomplete combustion.

2.      HON LUMNOUS FLAME: This has a blue colour. Its temperature is higher than the luminous flame. It is produced when air is made to flow along the pipe. There is complete combustion.

         

2.5           ULTMATE ANAYSIS OF THE FUEL GAS

The fuel gas used in this project is methane with ultimate analysis of carbon =12g by mass of the total mass.

Hydrogen = 4g by the total mass.

Methane (GH₄) =16g total mass.

Methane constitutes 92.6% by volume of a typical natural gas.

Combustion reaction for complete combustion

CH_4(g) +20^2(g)         C₀₂ + 2H0(g)

Combustion reaction for incomplete combustion

CH_4(g) + ²/3 0_2(g)              C_O(G)  +2H₂⁰_(g).

2.6 REQUIREMENT FOR GAS FUEL

1)                  it must attain a controllable uniform temperature in the burner.

2)                  The fuel mixture should be that which support combustion.

3)                    The fuel mixture should be the type that will react with the materials

the major fuel to be used is methane the simplest compound in the alkene series. It support combustion.

CHAPTER THREE

3.1           MATERIAL SELECTION

As a mandatory step in engineering design, before a material is selected, the general. Properties of such material, its manufacturing process, its chemicals composition has to be considered. In addition, the treatment it receives before  usage need to be considered. This will help to assess the prosperities and quality expected in the design.

In the course  of this project many engineering materials were open to us for a choice to be made. In all these, we looked for some properties before selecting

The properties are as follows

1)               Casting ability.

2)               Toughness of the material

3)               Malleability of the material

4)               Machinability of the material

5)               Ability of the material to withstand considerable heat (surface hardening).

6)               Durability of the material

7)               Ability to withstand indentation

8)               Availability of the material.

9)               Cost of the material

10)          Other properties including rigidity

Weight etc. with above the mind, a lot of engineering materials were considered fit  of these material/alloy that come into mind include galvanized steel, stainless steel, alloyed nickel, iron alloyed aluminum, Brass alloy, mid steel.

          Inspite of several alternatives, our final choice was based on cost with certain properties considered.

3.2           MILD STEEL

This is highly favored in the construction of the body of the gas burner. It posses in addition to the above properties, ability to withstand scratching, abrasion, indentation by harder  body. It can also be easily wielded.

3.3           BRASS

This used in the construction of the valve of the gas burner and tap because of its ductility and strength of its alloy.

3.4           CAST IRON

This is used in the construction of the burner. it has the ability to withstand heat.

3.5           HOSE

This is chose because of its availability and cost effectiveness.

3.6           COPPER PIPE

This is chosen because of its ductility for the construction of the flow channel of fluid. It is flexible, easily straightened to be in line with the frame of the gas burner.

                                                                            

CHAPTER FOUR

CONSTRUCTION PROCEDURE

4.1    The tools and equipment used in the construction of the two face gas burner are

1.      HAND SCRIBER: this was used in marking out the work piece

2.      MEASURING Tape: this was used to measure out the dimensions required of the design.

3.      VICE: this was used to clamp the work piece.

5.    HACK SAW: This was used in cutting the cook piece to the required size.

6.    Try square: this was used to check the squareness of the work piece.

7.    Electric’s are welding machine: this was used in welding the metal parts together.

8.    Drilling  machine: it was used for drilling holes for bolt and nut  

4.2          SEQUENCE OF OPERATION

OPERATION	EQUIPMENT USED	BRIEF DESCRIPTION	SKETCH	TIME
1)   Measuring	Measuring tape	After the material has been bought from the market, a tape calubrated in mm was used to measure out all the component parts required.
2)   Marking out	Hand scriber	Marking out of the measured parts was done with scriber held in hand like a pen.		30 mins
3)   cutting	Hack saw, file, try-square are and vice	Hack saw was used in cutting the angle bars, flat bars, which were clamped to the bench vice while cutting a try square was used to check the square-ness. The cutting was done slightly more than the actual dimension. File was later used to reduce it to its   actual dimension.		1 hour
4)   welding	Try square, welding electrode, Arc welding machine, Angle grander.	The squareness of the parts to be welded were checked with the try square. Frostily welding was done with lower amperage of 80 –100. Finally welding was done with 120-150 amperage so that it will have enough welding deposit. The surface of the work was smoothening with angle grander.
5)   Assembly of burner to frame of the gas  cooker	Welding electrode, Arc welding machine	The burner was set to be at the centre of each frame. It was then welded to the body of the frame.		2 hour
6)   Gas pipe assembly		The gas pipe was given three marks at different places and three sizes of the pipe were used. One was welded with the seating of the burner, the other ones were fixed into the pipe gas   line. It has nut, which holds it together. The last pipe was fitted to the body of the gas cooker. The two gas values were used.
7)   Drilling	Drilling machine	The holes through which the nut were fixed was drilled in the drilling machine and also the burner.		3 hour
8)   smoothening	Emery cloth	The body of the gas cooker frame and pipe were smoothened using emery cloth		1 hour
9)   painting	Painting brush and paint spraying machine	The body of the gas cooker was painted to prevent rusting. Ie  both the frame and the pipes		2 hour

                            

  

CHAPTER FIVE

ASSEMBLY OF THE PROJECT

5.1    FRONT VIEW

                                

CHAPTER SIX

COST OF PRODUCTION AND COST ANALYSIS

This deals with the total cost of accomplishing the project as seen below.

S/NO	MATERIAL	SPECIFICATION	COST(N)
1	Angle bar	18 feet (5485.4.mm)	800.00
2	Mild steel plate	10 feet (3048mm)	800.00
3	Rod (y25)	7 feet (2133.6mm)	300.00
4	Values (gas)		300.00
5	Electrode	3.2mm diameter	250.00
6	Paint	1 tin	800.00
7	Bolt	M6	80.00
8	Sand/Emery cloth		50.00
9	Copper tubing	12.25mm diameter	150.00
10	Hose	12.25mm	100.00
11	Cast iron burner		1000.00
12	Gas cylinder		3000.00

MACHINE COST

S/N	MACHINE	COST(N)
1	Cost of  hiring drilling machine	100.00
2	Cost of hiring oxyacetylene and arc welding machine	500.00
3	Cost of hiring hack-saw blade	100.00
4	Cost of hiring vice	100.00
5	Cost of hiring files	200.00
	TOTAL	1,000.00

Cost of transportation N1500.00

Therefore total cost for completing the project.

Material cost +machine cost + transportation = N10, 130.                 

CHAPTER SEVEN

MAINTENANCE OF THE DEVICE

          To ensure optimum life span of the device, it ought to be properly handled. The operation technique is very import i.e “on” and “off” whenever there is any deficit in the supply of the gas to the burner, the valve and cylinder content should be checked. The cylinder should be refilled if need be. 

          The burner should be cleaned by removing dirt’s, which sticks to it after each use. The valve should be removed and cleaned thoroughly when never low working condition id perceived, after which it should be fixed back.

          A pointed object like pin should be used to remove dirt from the nipple hole. If after the service, the valve still malfunctions, it should be replaced with new one.

7.1           SAFETY PRECAUTION

To safeguard the user and the device against injury and damage respectively, the following precaution should be noted.

1.)             Always lock the cylinder regulator and gas cooker valve after usage.

2.)             Gas leakage should always be checked, as this could lead to poisoning and explosion

3.)             The gas cooker should not be put on without a flame

4.)             It should be used in a well – aerated environment.

5.)             Water should not be used in putting off the flame

6.)             Children should be well instructed on how to operate the device one cannot automatically stop them from using it

7.2           TESTING OF THE DEVICE

After concluding the project the gas cooker was tested in the same shop with gad filled cylinder and it was observed. There was a non luminous (blue) flame and the gas was coming out almost simultaneously. The cooker can only produce a blue (non-luminous) flame if the oxygen flowing inside the burner is properly regulated.

7.3           RECONMENDATION

Since final year project is mandatory to all final year irrespective of the department, we wish to make the following  recommendations that the department should always inform the school authority to always make fund available for projects do that students can finish their final year project without difficulties.  That department should find the importation of new books and technological magazine into the department library n current basis.  This will change students into research and creativity.  That final year topic should be released as early as possible so that students can have time to make exhaustive research.

7.4    CONCLUSION

          Having completed the project, we came to realize that the task of collecting facts and data is influenced by wide range of factors such as time practical application of engineering knowledge in construction.

          This project has really directed our attention to research study and practical engineering application of the knowledge acquired so far.

          With this construction, our hearts and focus is aroused towards actualizing Nigeria dream of building a functional technology.

HOW TO GET THE FULL PROJECT WORK

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HOW TO RECEIVE PROJECT MATERIAL(S)

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Bank: GTBank.

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Account Number: 2023350498

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