Design And Construction Of Journal Bearing Demonstration Rig
A journal bearing demonstration rig is a specialized apparatus designed to showcase the operational principles and performance characteristics of journal bearings in various engineering applications. Utilizing precise instrumentation and controlled conditions, such a rig provides a practical platform for investigating crucial aspects such as friction, lubrication, load-bearing capacity, and thermal management within the context of journal bearing operation. This equipment facilitates hands-on learning experiences and empirical analysis, enabling engineers and students to gain insights into the intricate dynamics of journal bearings and their significance in diverse fields like automotive, aerospace, and industrial machinery. Through systematic experimentation and data analysis, users can discern the intricate interplay between design parameters, operating conditions, and performance metrics, thereby enhancing their understanding of bearing behavior and fostering innovations in bearing technology.
Title page
Certification page
Dedication
Acknowledgment
Abstract
Table of content
List of figures
List of tables
CHAPTER ONE
1.1 Introduction
1.2 Historical background
1.3 Research problem
1.4 Aims and objectives of this project
1.5 Scope of this project
CHAPTER TWO
2.1 Literature review
7 2.2 Theoretical background
2.2.1 Basics of bearings
2.2.2 Classification of bearings
2.2.3 Hydrodynamic lubricated bearings
2.2.4 Terms used in hydrodynamic journal bearing
2.2.5 Assumptions in Hydrodynamic Lubricated bearings
2.2.6 Important factors for thick oil film
2.2.7 Properties of bearing materials
2.3 Basic principle of Journal bearing
2.4 Working principle of journal bearing
2.5 Applications of Journal bearings
CHAPTER THREE
Design And Construction Of The Journal Bearing Demonstration Rig, And Equation Models Of Various Parts
3.1 Design of components
3.1.1 The journal shaft
3.1.1.1 Shaft analysis
3.1.1.2 Design
3 3.1.1.3 Dimensions
3.1.1.4 Construction
3.1.2 The journal bearing
3.1.2.1 The design calculation
3.1.2.2 Dimensions
3.1.2.3 Construction
3.1.3 The frame
3.1.3.1 Design
3.1.3.2 Dimensions
3.1.3 Construction
3.1.4 The Base plate
3.1.4.1 Design
3.1.4.2 Dimensions
35 3.1.4.3 Construction
3.1.5 Electric motor
3.1.5.1 Specification
3.1.5.2 Reason for selection
3.1.6 Coupling
3.1.6.1 Reason for selection
3.1.7 Oil pipes/tubes 3.1.7.1 Reason for selection
3.1.8 Fasteners
3.1.8.1 Functions 3.1.9 Lubricant (oil)
3.1.9.1 Properties of lubricants 3.1.9.2 Specification
3.1.9.3 Reason for selection
3.1.10 Oil collecting pan
3.1.11 Oil reservoir/tank
3.1.12 Spring damper support
3.2 Design consideration and selection of materials
3.3 Assembly of the apparatus
43 3.4 Working principle of the journal bearing test rig
3.5 Operating conditions
3.6 Operating instructions
3.7 Mathematical Models and Calculations
3.7.1 Bearing Characteristics number for journal bearing
3.7.2 Critical pressure of the journal bearing 3.7.3 Sommerfeld number
3.7.4 Heat generated in a journal bearing
3.7.5 Heat dissipated by the journal bearing
3.7.6 Calculation on pressure head
3.7.7 Derivation of Sommerfeld’s and Reynold’s equation
3.7.8 Derivation of Petroff’s equation
CHAPTER FOUR
Discussion Of Results, Maintenance Instruction, Safety Precautions
4.1 Discussion of results
4.2 Maintenance instruction
4.3 Safety precautions
4.4 Storage
CHAPTER FIVE
Project Cost Analysis, Challenges, Conclusion And Recommendation
5.1 Project Cost Analysis
5.2 Challenges
5.3 Conclusion
5.4 Recommendation
References
Appendix A
Appendix B
Appendix C
Appendix D
Appendix E
Appendix F
Appendix G
1.1 INTRODUCTION
Hydrodynamic journal bearings are typical critical power transmission components that carry high loads in different machines. In machine design, therefore, it is essential to know the true or expected operating conditions of the bearings. These operating conditions can be studied both by experimental and mathematical means, for example in test rig experiments, in field or laboratory tests with engines and by calculation or simulation. Numerous studies of the operating conditions of hydrodynamic journal bearings have been made during the last decades. Still, the case is far from closed. For example, there are a limited number of studies that carry out an indepth examination of the true operating conditions of bearings in true-scale experiments. There is also a need for experimental studies to verify the theoretical ones. Fluid friction i.e. viscosity which exists in the lubricant being used is studied alongside the pressure effect which is being generated in the bearing, thus the effect of lubricants with different viscosities are considered. A simple journal bearing consists of two rigid cylinders. The outer cylinder (bearing) wraps the inner rotating journal (shaft). A lubricant fills the
small annular gap or clearance between the journal and the bearing. The amount of eccentricity of the journal is related to the pressure that will be generated in the bearing to balance the radial load. The lubricant is supplied through a hole or a groove and may or may not extend all around the journal. The pressure around the journal is measured on various manometers by means of pressure pipe/tubes.
This is done at various speeds to get the relationship between speed and the pressure.
1.2 HISTORICAL BACKGROUND
In the late 1880s, experiments were being conducted on the lubrication of bearing surfaces. The idea of “floating” a load on a film of oil grew from the experiments of Beauchamp Tower and the theoretical work of Osborne Reynolds. Prior to the development of the pivoted shoe thrust bearing, marine propulsion relied on a “horseshoe” bearing which consisted of several equally spaced collars to share the load, each on a sector of a thrust plate. The parallel surfaces rubbed, wore, and produced considerable friction. Design unit loads were on the order of 40 psi. Comparison tests against a pivoted shoe thrust bearing of equal capacity showed that the pivoted shoe thrust bearing, at only 1/4 the size, had 1/7 the area but operated successfully with only 1/10 the frictional drag of the horseshoe bearing. In 1896, inspired by the work of Osborne Reynolds, Albert Kingsbury conceived and tested a pivoted shoe thrust bearing. According to Dr. Kingsbury, the test bearings ran well. Small loads were applied first, on the order of 50 psi (which was typical of ship propeller shaft unit loads at the time). The loads were gradually increased, finally reaching 4000 psi, the speed being about 285 rpm. In 1912, Albert Kingsbury was contracted by the Pennsylvania Water and Power Company to apply his design in their hydroelectric plant at Holtwood,
PA. The existing roller bearings were causing extensive down times (several outages a year) for inspections, repair and replacement. The first hydrodynamic pivoted shoe thrust bearing was installed in Unit 5 on June 22, 1912. At start-up of the 12,000 kW units, the bearing wiped. In resolving the reason for failure, much was learned about tolerances and finishes required for the hydrodynamic bearings to operate. After properly finishing the runner and fitting the bearing, the unit ran with continued good operation. This bearing, owing to its merit of running 75 years with negligible wear under a load of 220 tons, was designated by ASME as the 23rd International Historic Mechanical Engineering Landmark on June 27, 1987. Since then, there has been series of progressive research carried out on
bearings bringing to the advent of journal bearings which are not so different from the bearings designed by Osborne Reynolds and Albert Kingsbury which work on the same hydrodynamic lubrication system.
1.3 RESEARCH PROBLEM
The operating conditions of hydrodynamic journal bearings can be described by a set of tribological variables called key operating parameters. For example, the load level of a hydrodynamic journal bearing is described by two parameters: the specific load and the sliding speed. The key operating parameters most directly related to the bearing lubricant-shaft contact are the oil film temperature, oil film thickness and oil film pressure. These three key parameters can be determined by experimental or mathematical means with
varying levels of complexity. Until now, oil film pressure in hydrodynamic journal bearings has been studied mainly by mathematical means, because the experimental determination of oil film pressure has been a demanding or even an unfeasible task. Under real
operating conditions, there are typically many practicalities that complicate the experimental determination of true oil film pressure in a certain point or at a certain moment. The oil film may be extremely thin and therefore sensitive to different disturbing factors, for example defects in geometry. In addition, the level of the oil film pressure may be extremely high or have a high level of
dynamic variability.
1.4 AIM AND OBJECTIVE OF THE PROJECT
The research into the construction and design of the journal bearing apparatus has several reasons and purposes which need to be achieved and justified. The main aim of the study was to determine the oil film pressure in hydrodynamic journal bearings carrying realistic loads. In addition, the relationship between the oil film pressure and other key operating parameters of journal bearings such as eccentricity and shaft speed was studied. The study also included the determination of the relationship between the speed of rotation of the shaft, the pressure around the journal bearing and the oil thickness.
1.5 SCOPE OF THE PROJECT
The design and construction of journal bearing demonstration rig covers a very broad area. This area encompasses the design, design considerations, construction, assembly, working conditions and governing mathematical equations and laws. The design gives in depth details of the construction and fabrication of the apparatus. The working conditions consist of the loading, acting pressures and the variable operating speed which the journal bearing apparatus undergoes. Relevant design calculations and equations to include the
Pressure head calculation, Sommerfeld’s equation and number, Petroff’s equation and Reynold’s equation to mention a few, are contained in this work.
Design And Construction Of Journal Bearing Demonstration Rig:
Designing and constructing a journal bearing demonstration rig is a complex engineering project that requires careful planning and execution. A journal bearing demonstration rig is typically used for educational or research purposes to demonstrate the principles of lubrication, friction, and bearing design. Below, I’ll outline the general steps and considerations for designing and constructing such a rig:
1. Define the Objectives:
- Clearly define the objectives and learning outcomes for your demonstration rig. What specific principles or concepts do you want to demonstrate?
2. Select Bearing Type:
- Choose the type of journal bearing you want to demonstrate. Common types include hydrodynamic (fluid film) and hydrostatic (pressurized fluid) journal bearings.
3. Materials and Components:
- Determine the materials for the bearing and its components (e.g., shaft, housing, journal, bearing material). Common materials include steel, bronze, and other bearing alloys.
- Select appropriate seals and lubrication systems (e.g., oil bath, oil jet) based on your design.
4. Rig Design:
- Create detailed engineering drawings and specifications for the rig, including dimensions, tolerances, and clearances.
- Consider the layout and arrangement of components, ensuring easy access for observation and maintenance.
- Decide on the type of load (radial or axial) and the magnitude of the load to be applied to the bearing.
5. Lubrication System:
- Design a lubrication system that provides a controlled and consistent flow of lubricant to the bearing.
- Include sensors and instruments to measure lubricant flow rate and pressure.
6. Data Acquisition and Monitoring:
- Install sensors to collect data on temperature, pressure, friction, and other relevant parameters.
- Use data acquisition systems to record and display real-time data for analysis and observation.
7. Safety Considerations:
- Ensure the rig is designed with safety in mind. Implement safety features to protect users from moving parts and potential hazards.
8. Fabrication and Assembly:
- Fabricate the rig components according to your design specifications or enlist the help of a machine shop.
- Assemble the rig, making sure all components fit together precisely.
9. Instrumentation and Control:
- Set up the instrumentation and control systems to monitor and adjust variables as needed during experiments.
- Develop a control interface for users to interact with the rig.
10. Testing and Calibration:
- Conduct initial tests to calibrate the rig and verify its functionality.
- Fine-tune the rig to ensure it meets the defined learning objectives.
11. Documentation:
- Create comprehensive documentation, including operating manuals and safety guidelines.
- Provide guidelines on how to conduct experiments and record data.
12. User Training:
- Train users (students or researchers) on how to operate the rig safely and effectively.
13. Maintenance and Troubleshooting:
- Establish a maintenance schedule and procedures for troubleshooting and addressing common issues.
14. Experimentation and Data Analysis:
- Use the rig for experiments that demonstrate various aspects of journal bearing behavior.
- Analyze collected data to draw conclusions and reinforce learning objectives.
Remember that the design and construction of such a rig may involve a team of engineers, researchers, and technicians with expertise in mechanical engineering, fluid dynamics, and instrumentation. Additionally, safety should always be a top priority, especially when working with rotating machinery and high-pressure lubrication systems.