Design And Construction Of A Woodlathe Machine
A wood lathe machine is a versatile tool utilized in woodworking for shaping and sculpting wooden pieces. Employing rotational motion, it enables craftsmen to craft intricate designs and symmetrical shapes by securing the workpiece to a spindle and manipulating it with various cutting tools. The construction of a wood lathe involves several key components, including the bed, headstock, tailstock, tool rest, and motor. The bed provides a stable foundation and guides the movement of the tool rest along its length, while the headstock houses the motor and spindle responsible for rotating the workpiece. The tailstock supports the opposite end of the workpiece, ensuring stability during turning. Additionally, the tool rest facilitates precise cutting by offering a stable platform for the tools. The motor, typically mounted within the headstock, imparts rotational motion to the spindle, allowing for controlled shaping of the wood. By integrating sturdy materials, precise mechanisms, and ergonomic design, the construction of a wood lathe machine ensures efficiency, accuracy, and durability in woodworking operations, thereby enhancing productivity and enabling artisans to unleash their creativity in crafting bespoke wooden creations.
This work is an attempt to evolve a quicker and easier method of achieving cylindrical shape object from a work price. This will no double save considerable human labour and time wastage involved in traditional manual method of carving.
To achieve this preliminary experiment was carried out to determine the optimum speed of this machine various design alternatives for achieving the design solution were synthesized and a choice of an economic method which would satisfy the objective was made. Based on the principles guiding the performance of the machine, the dimensions and sizes of the various components were established.
Appropriate materials were subsequently selected and fabricated to required sizes. The machine was then assembled and tested.
After testing, it was found to perform efficiently thus satisfying the objective for which it was designed.
Title page
Approval Page
Dedication
Acknowledgement
Abstract
Table of Contents
CHAPTER ONE
1.0 Introduction
1.1 Objectives
1.2 Literature Review
1.3 Trend in Lather Machine
1.4 Dimensions and Specifications
1.5 Statement of Problems
1.6 Purpose of Study
1.7 Scope of Work
CHAPTER TWO
2.0 Synthesis of Solutions
2.1 Theory and Analysis of Problems
2.2 Materials Selection
CHAPTER THREE
3.0 Assembly Procedure
3.1 Testing and Evaluation
3.2 Operational/Safety Guide
3.3 General Maintenance
CHAPTER FOUR
4.0 Cost Analysis
4.1 Material Cost
4.2 Labour Cost
4.3 Overhead Cost
4.4 Summary of Costs
CHAPTER FIVE
5.0 Conclusion
5.1 Recommendation
References
1.0 INTRODUCTION
In recent times, the demand for interior decorations and cylindrical objects has been on the increase from the furniture and boundary industries. With it, comes the choice of various designs and models. In order to meet up with the increasing demand of the industries led to the design of a good number of machines that can be used by the craftsman to create different wood designs, amongst which is the wood lather machine.
1.1 OBJECTIVES
Apart from putting into practical the theoretical knowledge acquired from the class room, the main objectives of the project are:
a) To use available local materials in fabrication.
b) To achieve a reduction in the cost of production of the machine.
c) To reduce the labour cost and time spent on using hand tools for wood dressing.
d) To create awareness for, and encouragement of indigenous technology.
e) Increase productivity and creativity.
The vital need for the fabrication of a wood lathe is significant in the much delay and time as well as energy wasted in using simple hand took to carry out operations moreover, the cost of importation of a lather machine, is too high for average user.
Similar to the use of other machine tools, the wood lathes machine will help to reduce cost, save labour time and consequently increase the rate of production and craftsman’s skill. It is also important to explore the design of machines to improve on the ones already in existence.
By the early middle age the lathe is still driven by a cord, the new lathe used the tension of a bent tree branch or cut pole to provide a stronger and more convenient way of furring coordinated with the pole was a treadle, which pulled down on the cord wrapped around the work itself, or on a spindle attached to the work. The treadle regulates the speed at which the piece turned. This arrangement displeased with the need for an assistant. The troublesome feature of the early lathers that the pole and treadle system did not address was the need for continuous motion.
The search for a lather that would turn in only one direction probably ended in the fifteenth century, when the lathers powered by cranked flywheels and giant wheels powered by hand foot horse, and even water were invented, Leonardo a Vinci was one of the many inventors who designed the early continuous drive lather. However, today, wood lather machined are powered by an electric motor which provide the continuous motion needed.
Although, wood lathe machines are made from metal steel, iron etc.
1.2 LITERATURE REVIEW
Traditionally, it was thought that the ancient Egyptians introduced lather turning. Perhaps as much as 4,000 years ago. Despite a lack of hard evidence, it was assumed that a civilized nation as advanced as Egypt’s – is known to develop the Potter’s wheel and bow drill – possessed the technical know – how and skill to have made the invention of the lathe inevitable. Instead, scholars now believe that the lathe was invented around a thousand years B.C., and that its development may have occurred simultaneously among the Etrusians in Italy, the Celts in Great Britain, and the inhabitants of the Crimea. By the second century B.C., the lather was known to most of the people of the Near East and Europe. Originally, the lather was vertically oriented, like the Potter’s wheel. In the case of farning, the lather was eventually mounted on a table France, to be used mainly in a standing position. Virtually all early lathes were powered by cord and required that a helper assist the Craftsman and Non- metal (Hard wood). Those the frame made of wood are faced with the problem of durability and the ability to withstand shock.
However, the major problems that are prevalent with the existing lathes are:
1. Retching and vibration which translates into the spindle and bindweed thereby making it impossible to reduce anything accurately.
2. Base not rigid or heavy enough.
3. tai/stock base do not lock down well enough and operators often retightening it.
4. Tool rest do not lock down well enough.
Finally, as the furniture and founding industries demand for cylindrical object increases, the need for effective, economical and efficient lathe arise. To meet up with the industrial demand and combat the problems found in the existing wood lathe machines, hence the embarkment of this project.
1.3 TREND IN LATHE MACHINE FABRICATION
The emergence of the lathe machine dated back to some thousand years B.C., but it gained popularity between sixteenth and seventeenth centuries. Then opticians used it for cutting lenses, used in the construction of astronomical Telescopes. They modified the relatively rough technique for special purposes. Artisans and furniture makers used the large lathes in turning fancy works, though the frames were made of wood and headstock depending on the work being done.
Discussed below are some related lathe machines:
A) CENTRE LATHE MACHINE
The centre lathe is used to machine metals, by rotating the work piece mounted between centers against a cutting tool. The tool can be fed both transversely and longitudinally with respect to the turning axis of the job. The tool can be operated manually of automatically and many shapes as well as different works can be carried out on the centre lathe such work as cylindrical, eccentric or conical shapes can be machined. Also done on the centre lathe are threading and boring operations.
B) CERAMIC LATHE MACHINE
The ceramic lathe is used for ceramic machining alone, though the operation is similar to that of the centre lathe.
C) WOOD LATHE
The wood lathe, just like other types of lathe, can be used to carry out a wide range of machining operations. It saves time and does not need much skill as in the use of hand tools.
1.4 DIMENSIONS AND SPECIFICATIONS
Below are the dimensions and specification as regards the fabrication of the wood lathe machine.
1. Total length of the machine 1680mm
2. Total height of the machine 1200mm
3. With of the machine 240mm
4. The electric motor
Rpm 2820rpm
Horse power capacity 3hp
Power 2.2KW
Frequency 50Hz
Voltage 240V
Current 8.9/49A
5. The space between the bed rails 140mm
6. Diameter of the headstock pulley 137mm
7. Diameter of electric motor’s pulley 98mm
8. With of tailstock 240mm
9. V – belt A-56
10. Maximum length of work piece 1100mm
11. Minimum length of work piece 300mm
13. Maximum diameter of work piece 300mm
BACKGROUND INFORMATION
To improve the existing wood lathe machine so that the output is increase and operator fatigue is reduce.
CONDITION OF USE
Lathe to be used in workshop environment, it must be able to withstand mechanical vibration.
PERFORMANCE
Operation to be no noisier than when manually turned. Wood lather to be capable of an output higher than currently achieved in the existing once. The machine is to be operated continuously for a period of 8hours in a workshop environment without need for any attention.
CAPACITY
The machine capacity is the distance between centers and the swing which are the two basic measurement of capacity for lathe. The distance between centers is the maximum length of wood you can turn between the headstock and the tailstock. While the swing determines the diameter of the jobs that can be turned over the bed.
RELIABILITY AND LIFE
The machine must be sufficiently reliable compare with the existing once. Life expectancy for full loading at 8hours per day must exceed 20years.
1.5 STATEMENT OF PROBLEM
The continuous guest to have the problems of man and his growing needs solved has led to the establishment of factories and other industries, which necessitates an intermediate technology. However, simple hand tools that were in used before are no longer efficient for mass production. In the same manner the importation f wood lathe machine as a substitute for these tools, likewise has failed to meet man’s insatiable economy.
Then, there comes the need for urgent attention to a better and locally made wood lathe machine.
1.6 PURPOSE OF STUDY
The design and fabrication of wood lathe machine aims among other things at a maximum justification of a simple way of scraping and cutting off wood at its best quality at a minimum cost of labour, so that the financial burden of people can be reduced.
The simple design and construction of the machine, makes it viable reliable, and easy to carry out maintenance services at minimum bearable cost.
1.7 SCOPE OF WORK
Essentially, the machine comprises the frame made of metal, with the headstock fixed in position; the tailstock moves along the bed of the machine, and the tool rest mounted on a cross slide which can be moved both longitudinally and transversely on the bed. It is located between the headstock and the tailstock.
In operations, the machine is limited to only a turning and cutting of any type of wood. Drilling operations cannot be performed on the machine.
Design And Construction Of A Woodlathe Machine:
Designing and constructing a wood lathe machine is a complex engineering project that requires a deep understanding of mechanical and electrical systems, as well as access to specialized tools and materials. It’s important to prioritize safety during the design and construction process. Here, I’ll provide a high-level overview of the key components and steps involved in building a basic wood lathe machine.
Materials and Tools Needed:
- Steel Frame: You’ll need a sturdy steel frame to support the lathe components.
- Electric Motor: Choose a powerful electric motor that can provide variable speed control. A 1-2 horsepower motor should suffice for most woodworking tasks.
- Headstock and Tailstock: These are essential components of a lathe. The headstock holds the workpiece, and the tailstock provides support. They should be made from durable materials like cast iron.
- Spindle: The spindle connects to the motor and holds various accessories like chucks and faceplates.
- Tool Rest: This is a platform that supports cutting tools and slides along the bed of the lathe.
- Bed: The bed provides a stable base for the lathe components and should be made of cast iron for stability and rigidity.
- Tool Post: This holds the cutting tools and allows you to adjust their position.
- Variable Speed Control Unit: You’ll need a control unit to adjust the speed of the motor. This can be achieved using a variable frequency drive (VFD) for precise speed control.
- Belts and Pulleys: These are used to transmit power from the motor to the spindle. A step pulley system or a variable speed pulley can be used for speed control.
- Bearings: High-quality bearings are crucial for smooth and precise operation.
- Safety Guards: Install safety guards to protect the operator from flying wood chips and debris.
- Electrical Components: Wiring, switches, and a control panel for the motor and speed control.
Steps for Construction:
- Design the Lathe: Create detailed plans and drawings for your wood lathe, including dimensions and specifications for all components.
- Frame Construction: Build a robust steel frame that supports the lathe components. Ensure it is level and stable.
- Mount the Motor: Attach the electric motor to the frame and connect it to the spindle using belts and pulleys.
- Headstock and Tailstock: Attach the headstock and tailstock to the bed. Make sure they are aligned properly for precise turning.
- Spindle Assembly: Mount the spindle in the headstock and ensure it rotates smoothly.
- Tool Rest and Tool Post: Install the tool rest on the bed and the tool post on the headstock. Ensure they are adjustable and secure.
- Variable Speed Control: Set up the variable speed control unit and wire it to the motor. This allows you to control the lathe’s speed.
- Safety Features: Install safety guards and emergency stop switches to protect the operator.
- Testing: Before using the lathe, thoroughly test all components for proper operation and alignment.
- Fine-Tuning: Make any necessary adjustments to ensure accuracy and safety.
- Maintenance: Regularly inspect and maintain the lathe to ensure it continues to function properly and safely.
Please note that building a wood lathe machine is a complex and potentially hazardous project. It’s crucial to have a strong foundation in mechanical engineering and safety protocols. Additionally, local regulations and safety standards must be followed, and safety equipment should always be used when operating the lathe. If you are not experienced in this type of project, consider seeking help from a professional or purchasing a commercial wood lathe for your woodworking needs.