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The Best Mechanical Engineering Dissertation Topics and Titles

Published by Carmen Troy at January 5th, 2023 , Revised On May 2, 2024

Introduction 

Engineering is a vast subject that encompasses different branches for a student to choose from. Mechanical engineering is one of these branches , and one thing that trips students in the practical field is dissertation . Writing a mechanical engineering dissertation from scratch is a difficult task due to the complexities involved, but the job is still not impossible.

To write an excellent dissertation, you first need a stellar research topic. Are you looking to select the best mechanical engineering dissertation topic for your dissertation? To help you get started with brainstorming for mechanical engineering dissertation topics, we have developed a list of the latest topics that can be used for writing your mechanical engineering dissertation.

These topics have been developed by PhD-qualified writers on our team, so you can trust them to use these topics for drafting your own dissertation.

You may also want to start your dissertation by requesting a brief research proposal from our writers on any of these topics, which includes an introduction to the topic, research question, aim and objectives, literature review, and the proposed methodology of research to be conducted. Let us know  if you need any help in getting started.

Check our  dissertation example to get an idea of  how to structure your dissertation .

Review the step-by-step guide on how to write your own dissertation here.

Latest Mechanical Engineering Research Topics

Topic 1: an investigation into the applications of iot in autonomous and connected vehicles.

Research Aim: The research aims to investigate the applications of IoT in autonomous and connected vehicles

Objectives:

• To analyse the applications of IoT in mechanical engineering
• To evaluate the communication technologies in autonomous and connected vehicles.
• To investigate how IoT facilitates the interaction of smart devices in autonomous and connected vehicles

Topic 2: Evaluation of the impact of combustion of alternative liquid fuels on the internal combustion engines of automobiles

Research Aim: The research aims to evaluate the impact of the combustion of alternative liquid fuels on the internal combustion engines of automobiles

• To analyse the types of alternative liquid fuels for vehicles and their implications
• To investigate the benchmarking of alternative liquid fuels based on the principles of combustion performance.
• To evaluate the impact of combustion of alternative liquid fuels on the internal combustion engines of automobiles with conventional engines

Topic 3: An evaluation of the design and control effectiveness of production engineering on rapid prototyping and intelligent manufacturing

Research Aim: The research aims to evaluate the design and control effectiveness of production engineering on rapid prototyping and intelligent manufacturing

• To analyse the principles of design and control effectiveness of production engineering.
• To determine the principles of rapid prototyping and intelligent manufacturing for ensuring quality and performance effectiveness
• To evaluate the impact of production engineering on the design and control effectiveness of rapid prototyping and intelligent manufacturing.

Topic 4: Investigating the impact of industrial quality control on the quality, reliability and maintenance in industrial manufacturing

Research Aim: The research aims to investigate the impact of industrial quality control on the quality, reliability and maintenance in industrial manufacturing

• To analyse the concept and international standards associated with industrial quality control.
• To determine the strategies for maintaining quality, reliability and maintenance in manufacturing.
• To investigate the impact of industrial quality control on the quality, reliability and maintenance in industrial manufacturing.

Topic 5: Analysis of the impact of AI on intelligent control and precision of mechanical manufacturing

Research Aim: The research aims to analyse the impact of AI on intelligent control and precision of mechanical manufacturing

• To analyse the applications of AI in mechanical manufacturing
• To evaluate the methods of intelligent control and precision of the manufacturing
• To investigate the impact of AI on intelligent control and precision of mechanical manufacturing for ensuring quality and reliability

COVID-19 Mechanical Engineering Research Topics

Investigate the impacts of coronavirus on mechanical engineering and mechanical engineers..

Research Aim: This research will focus on identifying the impacts of Coronavirus on mechanical engineering and mechanical engineers, along with its possible solutions.

Research to study the contribution of mechanical engineers to combat a COVID-19 pandemic

Research Aim: This study will identify the contributions of mechanical engineers to combat the COVID-19 pandemic highlighting the challenges faced by them and their outcomes. How far did their contributions help combat the Coronavirus pandemic?

Research to know about the transformation of industries after the pandemic.

Research Aim: The study aims to investigate the transformation of industries after the pandemic. The study will answer questions such as, how manufacturing industries will transform after COVID-19. Discuss the advantages and disadvantages.

Damage caused by Coronavirus to supply chain of manufacturing industries

Research Aim: The focus of the study will be on identifying the damage caused to the supply chain of manufacturing industries due to the COVID-19 pandemic. What measures are taken to recover the loss and to ensure the continuity of business?

Research to identify the contribution of mechanical engineers in running the business through remote working.

Research Aim: This study will identify whether remote working is an effective way to recover the loss caused by the COVID-19 pandemic? What are its advantages and disadvantages? What steps should be taken to overcome the challenges faced by remote workers?

Dissertation Topics in Mechanical Engineering Design and Systems Optimization

Topic 1: mini powdered metal design and fabrication for mini development of waste aluminium cannes and fabrication.

Research Aim: The research will focus on producing and manufacturing copula furnaces and aluminium atomisers with available materials to manufacture aluminium powder metal.0.4 kg of refined coke will be chosen to measure content and energy balance and calculate the design values used to produce the drawings.

Topic 2: Interaction between the Fluid, Acoustic, and vibrations

Research Aim: This research aims to focus on the interaction between the Fluid, Acoustic, and vibrations

Topic 3: Combustion and Energy Systems.

Research Aim: This research aims to identify the relationship between Combustion and Energy Systems

Topic 4: Study on the Design and Manufacturing

Research Aim: This research will focus on the importance of design and manufacturing

Topic 5: Revolution in the Design Engineering

Research Aim: This research aims to highlight the advances in design engineering

Topic 6: Optimising HVAC Systems for Energy Efficiency

Research Aim: The study investigates different design configurations and operational strategies to optimise heating, ventilation, and air conditioning (HVAC) systems for energy efficiency while maintaining indoor comfort levels.

Topic 7: Impact of Building Design Parameters on Indoor Thermal Comfort

Research Aim: The research explores the impact of building design parameters, such as insulation, glazing, shading, and ventilation, on indoor thermal comfort and energy consumption.

Topic 8: An Empirical Analysis of Enhanced Security and Privacy Measures for Call Taxi Metres

Research Aim: The research explores the methods to enhance the security and privacy of call taxi meter systems. It explores encryption techniques for sensitive data transmission and authentication protocols for driver and passenger verification.

Topic 9: An Investigation of Optimising Manifold Design

Research Aim: The study investigates various designs for manifolds used in HBr/HCl charging systems. It focuses on factors such as material compatibility, pressure control, flow rates, and safety protocols. 

Topic 10: Implementation of a Plant Lean Transformation

Research Aim: The research examines the implementation process and outcomes of a Lean Transformation in a plant environment. It focuses on identifying the key factors contributing to successful adoption and sustained improvement in operational efficiency. 

Topic 11: Exploring Finite Element Analysis (FEA) of Torque Limiters

Research Aim: Exploring the use of FEA techniques to simulate the behaviour of torque limiters under various loading conditions. The research provides insights into stress distribution and deformation.

Dissertation Topics in Mechanical Engineering Innovations and Materials Analysis

Topic 1: an overview of the different research trends in the field of mechanical engineering..

Research Aim: This research aims to analyse the main topics of mechanical engineering explored by other researchers in the last decade and the research methods. The data used is accumulated from 2009 to 2019. The data used for this research is used from the “Applied Mechanics Review” magazine.

Topic 2: The Engineering Applications of Mechanical Metamaterials.

Research Aim: This research aims to analyse the different properties of various mechanical metamaterials and how they can be used in mechanical engineering. This research will also discuss the potential uses of these materials in other industries and future developments in this field.

Topic 3: The Mechanical Behaviour of Materials.

Research Aim: This research will look into the properties of selected materials for the formation of a product. The study will take the results of tests that have already been carried out on the materials. The materials will be categorised into two classes from the already prepared results, namely destructive and non-destructive. The further uses of the non-destructive materials will be discussed briefly.

Topic 4: Evaluating and Assessment of the Flammable and Mechanical Properties of Magnesium Oxide as a Material for SLS Process.

Research Aim: The research will evaluate the different properties of magnesium oxide (MgO) and its potential use as a raw material for the SLS (Selective Laser Sintering) process. The flammability and other mechanical properties will be analysed.

Topic 5: Analysing the Mechanical Characteristics of 3-D Printed Composites.

Research Aim: This research will study the various materials used in 3-D printing and their composition. This research will discuss the properties of different printing materials and compare the harms and benefits of using each material.

Topic 6: Evaluation of a Master Cylinder and Its Use.

Research Aim: This research will take an in-depth analysis of a master cylinder. The material used to create the cylinder, along with its properties, will be discussed. The use of the master cylinder in mechanical engineering will also be explained.

Topic 7: Manufacturing Pearlitic Rail Steel After Re-Modelling Its Mechanical Properties.

Research Aim: This research will look into the use of modified Pearlitic rail steel in railway transportation. Modifications of tensile strength, the supported weight, and impact toughness will be analysed. Results of previously applied tests will be used.

How Can ResearchProspect Help?

ResearchProspect writers can send several custom topic ideas to your email address. Once you have chosen a topic that suits your needs and interests, you can order for our dissertation outline service , which will include a brief introduction to the topic, research questions , literature review , methodology , expected results , and conclusion . The dissertation outline will enable you to review the quality of our work before placing the order for our full dissertation writing service !

Electro-Mechanical Dissertation Topics

Topic 8: studying the electro-mechanical properties of multi-functional glass fibre/epoxy reinforced composites..

Research Aim: This research will study the properties of epoxy-reinforced glass fibres and their use in modern times. Features such as tensile strength and tensile resistance will be analysed using Topic 13: Studying the Mechanical and Durability different current strengths. Results from previous tests will be used to explain their properties.

Topic 9: Comparing The Elastic Modules of Different Materials at Different Strain Rates and Temperatures.

Research Aim: This research will compare and contrast a selected group of materials and look into their elastic modules. The modules used are the results taken from previously carried out experiments. This will explain why a particular material is used for a specific purpose.

Topic 10: Analysing The Change in The Porosity and Mechanical Properties of Concrete When Mixed With Coconut Sawdust.

Research Aim: This research will analyse the properties of concrete that are altered when mixed with coconut sawdust. Porosity and other mechanical properties will be evaluated using the results of previous experiments. The use of this type of concrete in the construction industry will also be discussed.

Topic 11: Evaluation of The Thermal Resistance of Select Materials in Mechanical Contact at Sub-Ambient Temperatures.

Research Aim: In this research, a close evaluation of the difference in thermal resistance of certain materials when they come in contact with a surface at sub-ambient temperature. The properties of the materials at the temperature will be noted. Results from previously carried out experiments will be used. The use of these materials will be discussed and explained, as well.

Topic 12: Analysing The Mechanical Properties of a Composite Sandwich by Using The Bending Test.

Research Aim: In this research, we will analyse the mechanical properties of the components of a composite sandwich through the use of the bending test. The results of the tests previously carried out will be used. The research will take an in-depth evaluation of the mechanical properties of the sandwich and explain the means that it is used in modern industries.

Mechanical Properties Dissertation Topics

Topic 13: studying the mechanical and durability properties of magnesium silicate hydrate binders in concrete..

Research Aim: In this research, we will evaluate the difference in durability and mechanical properties between regular concrete binders and magnesium silicate hydrate binders. The difference between the properties of both binders will indicate which binder is better for concrete. Features such as tensile strength and weight it can support are compared.

Topic 14: The Use of Submersible Pumping Systems.

Research Aim: This research will aim to analyse the use of a submersible pumping system in machine systems. The materials used to make the system, as well as the mechanical properties it possesses, will be discussed.

Topic 15: The Function of a Breather Device for Internal Combustion Engines.

Research Aim: In this research, the primary function of a breather device for an internal combustion engine is discussed. The placement of this device in the system, along with its importance, is explained. The effects on the internal combustion engine if the breather device is removed will also be observed.

Topic 16: To Study The Compression and Tension Behaviour of Hollow Polyester Monofilaments.

Research Aim: This research will focus on the study of selected mechanical properties of hollow polyester monofilaments. In this case, the compression and tension behaviour of the filaments is studied. These properties are considered in order to explore the future use of these filaments in the textile industry and other related industries.

Topic 17: Evaluating the Mechanical Properties of Carbon-Nanotube-Reinforced Cementous Materials.

Research Aim: This research will focus on selecting the proper carbon nanotube type, which will be able to improve the mechanical properties of cementitious materials. Changes in the length, diameter, and weight-based concentration of the nanotubes will be noted when analysing the difference in the mechanical properties. One character of the nanotubes will be of optimal value while the other two will be altered. Results of previous experiments will be used.

Topic 18: To Evaluate the Process of Parallel Compression in LNG Plants Using a Positive Displacement Compressor

Research Aim: This research aims to evaluate a system and method in which the capacity and efficiency of the process of liquefaction of natural gas can avoid bottlenecking in its refrigerant compressing system. The Advantages of the parallel compression system in the oil and gas industry will be discussed.

Topic 19: Applying Particulate Palm Kernel Shell Reinforced Epoxy Composites for Automobiles.

Research Aim: In this research, the differences made in applying palm kernel shell particulate to reinforced epoxy composites for the manufacturing of automobile parts will be examined. Properties such as impact toughness, wear resistance, flexural, tensile, and water resistance will be analysed carefully. The results of the previous tests will be used. The potential use of this material will also be discussed.

Topic 20: Changes Observed in The Mechanical Properties of Kevlar KM2-600 Due to Abrasions.

Research Aim: This research will focus on observing the changes in the mechanical properties of Kevlar KM2-600 in comparison to two different types of S glass tows (AGY S2 and Owens Corning Shield Strand S). Surface damage, along with fibre breakage, will be noted in all three fibres. The effects of the abrasions on all three fibres will be emphasised. The use of Kevlar KM2 and the other S glass tows will also be discussed, along with other potential applications.

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Industrial Application of Mechanical Engineering Dissertation Topics

Topic 1: the function of a fuel injector device..

Research Aim: This research focuses on the function of a fuel injector device and why this component is necessary for the system of an internal combustion engine. The importance of this device will be explained. The adverse effects on the entire system if the equipment is either faulty or completely removed will also be discussed.

Topic 2: To Solve Optimization Problems in a Mechanical Design by The Principles of Uncertainty.

Research Aim: This research will aim to formulate an optimization in a mechanical design under the influence of uncertainty. This will create an efficient tool that is based on the conditions of each optimisation under the risk. This will save time and allow the designer to obtain new information in regard to the stability of the performance of his design under uncertainties.

Topic 3: Analysing The Applications of Recycled Polycarbonate Particle Materials and Their Mechanical Properties.

Research Aim: This research will evaluate the mechanical properties of different polycarbonate materials and their potential to be recycled. The materials that can be recycled are then further examined for potential use as 3-dimensional printing materials. The temperature of the printer’s nozzle, along with the nozzle velocity matrix from previous experiments, is used to evaluate the tensile strength of the printed material. Other potential uses of these materials are also discussed.

Topic 4: The Process of Locating a Lightning Strike on a Wind Turbine.

Research Aim: This research will provide a detailed explanation of the process of detecting a lightning strike on a wind turbine. The measurement of the magnitude of the lightning strike, along with recognising the affected area will be explained. The proper method employed to rectify the damage that occurred by the strike will also be discussed.

Topic 5: Importance of a Heat Recovery Component in an Internal Combustion Engine for an Exhaust Gas System.

Research Aim: The research will take an in-depth evaluation of the different mechanics of a heat recovery component in an exhaust gas system. The functions of the different parts of the heat recovery component will be explained along with the importance of the entire element itself. The adverse effect of a faulty defective heat recovery component will also be explained.

“Feel free to contact us if you require custom dissertation topics and titles for your dissertation. ResearchProspect Ltd is a UK registered academic writing company which can provide you with highly qualified writers to assist you in the process of the formation of your dissertation. For more information about the type of services we offer.“

Related: Civil Engineering Dissertation

Important Notes:

As a student of mechanical engineering looking to get good grades, it is essential to develop new ideas and experiment on existing mechanical engineering theories – i.e., to add value and interest to the topic of your research.

The field of mechanical engineering is vast and interrelated to so many other academic disciplines like  civil engineering ,  construction ,  law , and even  healthcare . That is why it is imperative to create a mechanical engineering dissertation topic that is particular, sound and actually solves a practical problem that may be rampant in the field.

We can’t stress how important it is to develop a logical research topic; it is the basis of your entire research. There are several significant downfalls to getting your topic wrong: your supervisor may not be interested in working on it, the topic has no academic creditability, the research may not make logical sense, and there is a possibility that the study is not viable.

This impacts your time and efforts in  writing your dissertation as you may end up in a cycle of rejection at the very initial stage of the dissertation. That is why we recommend reviewing existing research to develop a topic, taking advice from your supervisor, and even asking for help in this particular stage of your dissertation.

Keeping our advice in mind while developing a research topic will allow you to pick one of the best mechanical engineering dissertation topics that not only fulfill your requirement of writing a research paper but also add to the body of knowledge.

Therefore, it is recommended that when finalizing your dissertation topic, you read recently published literature in order to identify gaps in the research that you may help fill.

Remember- dissertation topics need to be unique, solve an identified problem, be logical, and can also be practically implemented. Take a look at some of our sample mechanical engineering dissertation topics to get an idea for your own dissertation.

How to Structure Your Mechanical Engineering Dissertation

A well-structured   dissertation can help students   to achieve a high overall academic grade.

• A Title Page
• Acknowledgments
• Declaration
• Abstract: A summary of the research completed
• Table of Contents
• Introduction : This chapter includes the project rationale, research background, key research aims and objectives, and the research problems to be addressed. An outline of the structure of a dissertation can also be added to this chapter.
• Literature Review :  This chapter presents relevant theories and frameworks by analysing published and unpublished literature available on the chosen research topic in light of research questions to be addressed. The purpose is to highlight and discuss the relative weaknesses and strengths of the selected research area whilst identifying any research gaps. Break down of the topic and key terms can have a positive impact on your dissertation and your tutor.
• Methodology: The  data collection  and  analysis methods and techniques employed by the researcher are presented in the Methodology chapter, which usually includes  research design, research philosophy, research limitations, code of conduct, ethical consideration, data collection methods, and  data analysis strategy .
• Findings and Analysis: The findings of the research are analysed in detail under the Findings and Analysis chapter. All key findings/results are outlined in this chapter without interpreting the data or drawing any conclusions. It can be useful to include  graphs , charts, and   tables in this chapter to identify meaningful trends and relationships.
• Discussion and  Conclusion: The researcher presents his interpretation of results in this chapter and states whether the research hypothesis has been verified or not. An essential aspect of this section of the paper is to draw a linkage between the results and evidence from the literature. Recommendations with regard to the implications of the findings and directions for the future may also be provided. Finally, a summary of the overall research, along with final judgments, opinions, and comments, must be included in the form of suggestions for improvement.
• References:  This should be completed in accordance with your University’s requirements
• Bibliography
• Appendices: Any additional information, diagrams, graphs that were used to  complete the  dissertation  but not part of the dissertation should be included in the Appendices chapter. Essentially, the purpose is to expand the information/data.

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Our team of writers is highly qualified. They are experts in their respective fields. They have been working in the industry for a long, thus are aware of the issues as well as the trends of the industry they are working in.

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To discover mechanical engineering dissertation topics:

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• Opt for a niche aligning with your passion and career aims.

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Home > Engineering > MIE > ME_THESES

Mechanical Engineering Masters Theses Collection

Theses from 2024 2024.

TECHNICAL EVALUATION OF FLOATING OFFSHORE WIND PLANTS AND INSTALLATION OPERATIONS , CENGIZHAN CENGIZ, Mechanical Engineering

Heat Transfer Enhacement of Latent Heat Thermal Enery Storage , Joe Hatem T. Saba, Mechanical Engineering

Theses from 2023 2023

Device Design for Inducing Aneurysm-Susceptible Flow Conditions Onto Endothelial Cells , hans f. foelsche, Mechanical Engineering

Thermal Conductivity and Mechanical Properties of Interlayer-Bonded Graphene Bilayers , Afnan Mostafa, Mechanical Engineering

Wind-Wave Misalignment Effects on Multiline Anchor Systems for Floating Offshore Wind Turbines , Doron T. Rose, Mechanical Engineering

Theses from 2022 2022

A Simplified Fluid Dynamics Model of Ultrafiltration , Christopher Cardimino, Mechanical Engineering

Local Nanomechanical Variations of Cold-sprayed Tantalum Coatings , Dhrubajyoti Chowdhury, Mechanical Engineering

Aerodynamically Augmented Air-Hockey Pucks , Madhukar Prasad, Mechanical Engineering

Analysis of Low-Induction Rotors for Increased Power Production , Jack E. Rees, Mechanical Engineering

Application of the New IEC International Design Standard for Offshore Wind Turbines to a Reference Site in the Massachusetts Offshore Wind Energy Area , Samuel C. Roach, Mechanical Engineering

Applications of Thermal Energy Storage with Electrified Heating and Cooling , Erich Ryan, Mechanical Engineering

Theses from 2021 2021

Design and Testing of a Foundation Raised Oscillating Surge Wave Energy Converter , Jacob R. Davis, Mechanical Engineering

Wind Turbine Power Production Estimation for Better Financial Agreements , Shanon Fan, Mechanical Engineering

Finite Element Analysis of Impact and Cohesion of Cold Sprayed Particles onto Non-Planar Surfaces , Zhongkui Liu, Mechanical Engineering

Mechanical Design and Analysis: High-Precision Microcontact Printhead for Roll-to-Roll Printing of Flexible Electronics , Mehdi Riza, Mechanical Engineering

Jet Breakup Dynamics of Inkjet Printing Fluids , Kashyap Sundara Rajan, Mechanical Engineering

Ground Source Heat Pumps: Considerations for Large Facilities in Massachusetts , Eric Wagner, Mechanical Engineering

Theses from 2020 2020

Modeling of Electrical Grid Systems to Evaluate Sustainable Electricity Generation in Pakistan , Muhammad Mustafa Amjad, Mechanical Engineering

A Study on Latent Thermal Energy Storage (LTES) using Phase Change Materials (PCMs) 2020 , Ritvij Dixit, Mechanical Engineering

SunDown: Model-driven Per-Panel Solar Anomaly Detection for Residential Arrays , Menghong Feng, Mechanical Engineering

Nozzle Clogging Prevention and Analysis in Cold Spray , Alden Foelsche, Mechanical Engineering

Short Term Energy Forecasting for a Microgird Load using LSTM RNN , Akhil Soman, Mechanical Engineering

Optimization of Thermal Energy Storage Sizing Using Thermodynamic Analysis , Andrew Villanueva, Mechanical Engineering

Fabrication of Binder-Free Electrodes Based on Graphene Oxide with CNT for Decrease of Resistance , Di Zhang, Mechanical Engineering

Theses from 2019 2019

Computational Fluid Dynamics Models of Electromagnetic Levitation Experiments in Reduced Gravity , Gwendolyn Bracker, Mechanical Engineering

Forecasting the Cost of Electricity Generated by Offshore Wind Turbines , Timothy Costa, Mechanical Engineering

Optical-Fiber-Based Laser-Induced Cavitation for Dynamic Mechanical Characterization of Soft Materials , Qian Feng, Mechanical Engineering

On the Fuel Spray Applications of Multi-Phase Eulerian CFD Techniques , Gabriel Lev Jacobsohn, Mechanical Engineering

Topology Network Optimization of Facility Planning and Design Problems , Ravi Ratan Raj Monga, Mechanical Engineering

The Promise of VR Headsets: Validation of a Virtual Reality Headset-Based Driving Simulator for Measuring Drivers’ Hazard Anticipation Performance , Ganesh Pai Mangalore, Mechanical Engineering

Ammonia Production from a Non-Grid Connected Floating Offshore Wind-Farm: A System-Level Techno-Economic Review , Vismay V. Parmar, Mechanical Engineering

Calculation of Scalar Isosurface Area and Applications , Kedar Prashant Shete, Mechanical Engineering

Theses from 2018 2018

Electroplating of Copper on Tungsten Powder , Richard Berdos, Mechanical Engineering

A NUMERICAL FLUTTER PREDICTOR FOR 3D AIRFOILS USING THE ONERA DYNAMIC STALL MODEL , Pieter Boersma, Mechanical Engineering

Streamwise Flow-Induced Oscillations of Bluff Bodies - The Influence of Symmetry Breaking , Tyler Gurian, Mechanical Engineering

Thermal Radiation Measurement and Development of Tunable Plasmonic Thermal Emitter Using Strain-induced Buckling in Metallic Layers , Amir Kazemi-Moridani, Mechanical Engineering

Restructuring Controllers to Accommodate Plant Nonlinearities , Kushal Sahare, Mechanical Engineering

Application and Evaluation of Lighthouse Technology for Precision Motion Capture , Soumitra Sitole, Mechanical Engineering

High Strain Rate Dynamic Response of Aluminum 6061 Micro Particles at Elevated Temperatures and Varying Oxide Thicknesses of Substrate Surface , Carmine Taglienti, Mechanical Engineering

The Effects of Mechanical Loading and Tumor Factors on Osteocyte Dendrite Formation , Wenbo Wang, Mechanical Engineering

Microenvironment Regulates Fusion of Breast Cancer Cells , Peiran Zhu, Mechanical Engineering

Design for Sustainability through a Life Cycle Assessment Conceptual Framework Integrated within Product Lifecycle Management , Renpeng Zou, Mechanical Engineering

Theses from 2017 2017

Improving the Efficiency of Wind Farm Turbines using External Airfoils , Shujaut Bader, Mechanical Engineering

Evaluation Of Impedance Control On A Powered Hip Exoskeleton , Punith condoor, Mechanical Engineering

Experimental Study on Viscoelastic Fluid-Structure Interactions , Anita Anup Dey, Mechanical Engineering

BMI, Tumor Lesion and Probability of Femur Fracture: a Probabilistic Biomechanics Approach , Zhi Gao, Mechanical Engineering

A Magnetic Resonance Compatible Knee Extension Ergometer , Youssef Jaber, Mechanical Engineering

Non-Equispaced Fast Fourier Transforms in Turbulence Simulation , Aditya M. Kulkarni, Mechanical Engineering

INCORPORATING SEASONAL WIND RESOURCE AND ELECTRICITY PRICE DATA INTO WIND FARM MICROSITING , Timothy A. Pfeiffer, Mechanical Engineering

Effects of Malformed or Absent Valves to Lymphatic Fluid Transport and Lymphedema in Vivo in Mice , Akshay S. Pujari, Mechanical Engineering

Electroless Deposition & Electroplating of Nickel on Chromium-Nickel Carbide Powder , Jeffrey Rigali, Mechanical Engineering

Numerical Simulation of Multi-Phase Core-Shell Molten Metal Drop Oscillations , Kaushal Sumaria, Mechanical Engineering

Theses from 2016 2016

Cold Gas Dynamic Spray – Characterization of Polymeric Deposition , Trenton Bush, Mechanical Engineering

Intent Recognition Of Rotation Versus Translation Movements In Human-Robot Collaborative Manipulation Tasks , Vinh Q. Nguyen, Mechanical Engineering

A Soft Multiple-Degree of Freedom Load Cell Based on The Hall Effect , Qiandong Nie, Mechanical Engineering

A Haptic Surface Robot Interface for Large-Format Touchscreen Displays , Mark Price, Mechanical Engineering

Numerical Simulation of High Velocity Impact of a Single Polymer Particle during Cold Spray Deposition , Sagar P. Shah, Mechanical Engineering

Tunable Plasmonic Thermal Emitter Using Metal-Coated Elastomeric Structures , Robert Zando, Mechanical Engineering

Theses from 2015 2015

Thermodynamic Analysis of the Application of Thermal Energy Storage to a Combined Heat and Power Plant , Benjamin McDaniel, Mechanical Engineering

Towards a Semantic Knowledge Management Framework for Laminated Composites , Vivek Premkumar, Mechanical Engineering

A CONTINOUS ROTARY ACTUATION MECHANISM FOR A POWERED HIP EXOSKELETON , Matthew C. Ryder, Mechanical Engineering

Optimal Topological Arrangement of Queues in Closed Finite Queueing Networks , Lening Wang, Mechanical Engineering

Creating a New Model to Predict Cooling Tower Performance and Determining Energy Saving Opportunities through Economizer Operation , Pranav Yedatore Venkatesh, Mechanical Engineering

Theses from 2014 2014

New Generator Control Algorithms for Smart-Bladed Wind Turbines to Improve Power Capture in Below Rated Conditions , Bryce B. Aquino, Mechanical Engineering

UBOT-7: THE DESIGN OF A COMPLIANT DEXTEROUS MOBILE MANIPULATOR , Jonathan Cummings, Mechanical Engineering

Design and Control of a Two-Wheeled Robotic Walker , Airton R. da Silva Jr., Mechanical Engineering

Free Wake Potential Flow Vortex Wind Turbine Modeling: Advances in Parallel Processing and Integration of Ground Effects , Nathaniel B. Develder, Mechanical Engineering

Buckling of Particle-Laden Interfaces , Theo Dias Kassuga, Mechanical Engineering

Modeling Dynamic Stall for a Free Vortex Wake Model of a Floating Offshore Wind Turbine , Evan M. Gaertner, Mechanical Engineering

An Experimental Study of the C-Start of a Mechanical Fish , Benjamin Kandaswamy Chinna Thambi, Mechanical Engineering

Measurement and Verification - Retro-Commissioning of a LEED Gold Rated Building Through Means of an Energy Model: Are Aggressive Energy Simulation Models Reliable? , Justin M. Marmaras, Mechanical Engineering

Development of a Support Structure for Multi-Rotor Wind Turbines , Gaurav Murlidhar Mate, Mechanical Engineering

Towards Accessible, Usable Knowledge Frameworks in Engineering , Jeffrey Mcpherson, Mechanical Engineering

A Consistent Algorithm for Implementing the Space Conservation Law , Venkata Pavan Pillalamarri Narasimha Rao, Mechanical Engineering

Kinetics of Aluminization and Homogenization in Wrought H-X750 Nickel-Base Superalloy , Sean Reilly, Mechanical Engineering

Single-Phase Turbulent Enthalpy Transport , Bradley J. Shields, Mechanical Engineering

CFD Simulation of the Flow around NREL Phase VI Wind Turbine , Yang Song, Mechanical Engineering

Selection of Outputs for Distributed Parameter Systems by Identifiability Analysis in the Time-scale Domain , Teergele, Mechanical Engineering

The Optimization of Offshore Wind Turbine Towers Using Passive Tuned Mass Dampers , Onur Can Yilmaz, Mechanical Engineering

Design of a Passive Exoskeleton Spine , Haohan Zhang, Mechanical Engineering

TURBULENT TRANSITION IN ELECTROMAGNETICALLY LEVITATED LIQUID METAL DROPLETS , Jie Zhao, Mechanical Engineering

Theses from 2013 2013

Optimization of Mixing in a Simulated Biomass Bed Reactor with a Center Feeding Tube , Michael T. Blatnik, Mechanical Engineering

Continued Development of a Chilled Water System Analysis Tool for Energy Conservation Measures Evaluation , Ghanshyam Gaudani, Mechanical Engineering

Application of Finite Element Method in Protein Normal Mode Analysis , Chiung-fang Hsu, Mechanical Engineering

Asymmetric Blade Spar for Passive Aerodynamic Load Control , Charles Mcclelland, Mechanical Engineering

Background and Available Potential Energy in Numerical Simulations of a Boussinesq Fluid , Shreyas S. Panse, Mechanical Engineering

Techno-Economic Analysis of Hydrogen Fuel Cell Systems Used as an Electricity Storage Technology in a Wind Farm with Large Amounts of Intermittent Energy , Yash Sanghai, Mechanical Engineering

Multi Rotor Wind Turbine Design And Cost Scaling , Preeti Verma, Mechanical Engineering

Activity Intent Recognition of the Torso Based on Surface Electromyography and Inertial Measurement Units , Zhe Zhang, Mechanical Engineering

Theses from 2012 2012

Simulations of Non-Contact Creep in Regimes of Mixed Dominance , Maija Benitz, Mechanical Engineering

Techniques for Industrial Implementation of Emerging Semantic Technologies , Jay T. Breindel, Mechanical Engineering

Environmental Impacts Due to Fixed and Floating Offshore Wind Turbines , Micah K. Brewer, Mechanical Engineering

Physical Model of the Feeding Strike of the Mantis Shrimp , Suzanne M. Cox, Mechanical Engineering

Investigating the Relationship Between Material Property Axes and Strain Orientations in Cebus Apella Crania , Christine M. Dzialo, Mechanical Engineering

A Multi-Level Hierarchical Finite Element Model for Capillary Failure in Soft Tissue , Lu Huang, Mechanical Engineering

Finite Element Analysis of a Femur to Deconstruct the Design Paradox of Bone Curvature , Sameer Jade, Mechanical Engineering

Vortex-Induced Vibrations of an Inclined Cylinder in Flow , Anil B. Jain, Mechanical Engineering

Experimental Study of Stability Limits for Slender Wind Turbine Blades , Shruti Ladge, Mechanical Engineering

Semi-Active Damping for an Intelligent Adaptive Ankle Prosthesis , Andrew K. Lapre, Mechanical Engineering

A Finite Volume Approach For Cure Kinetics Simulation , Wei Ma, Mechanical Engineering

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Top 150 Mechanical Engineering Research Topics [Updated]

Mechanical engineering is an intriguing discipline that holds significant sway in shaping our world. With a focus on crafting inventive machinery and fostering sustainable energy initiatives, mechanical engineers stand as pioneers in driving technological progress. However, to make meaningful contributions to the field, researchers must carefully choose their topics of study. In this blog, we’ll delve into various mechanical engineering research topics, ranging from fundamental principles to emerging trends and interdisciplinary applications.

How to Select Mechanical Engineering Research Topics?

Table of Contents

Selecting the right mechanical engineering research topics is crucial for driving impactful innovation and addressing pressing challenges. Here’s a step-by-step guide to help you choose the best research topics:

• Identify Your Interests: Start by considering your passions and areas of expertise within mechanical engineering. What topics excite you the most? Choosing a subject that aligns with your interests will keep you motivated throughout the research process.
• Assess Current Trends: Stay updated on the latest developments and trends in mechanical engineering. Look for emerging technologies, pressing industry challenges, and areas with significant research gaps. These trends can guide you towards relevant and timely research topics.
• Conduct Literature Review: Dive into existing literature and research papers within your field of interest. Identify gaps in knowledge, unanswered questions, or areas that warrant further investigation. Building upon existing research can lead to more impactful contributions to the field.
• Consider Practical Applications: Evaluate the practical implications of potential research topics. How will your research address real-world problems or benefit society? Choosing topics with tangible applications can increase the relevance and impact of your research outcomes.
• Consult with Advisors and Peers: Seek guidance from experienced mentors, advisors, or peers in the field of mechanical engineering. Discuss your research interests and potential topics with them to gain valuable insights and feedback. Their expertise can help you refine your ideas and select the most promising topics.
• Define Research Objectives: Clearly define the objectives and scope of your research. What specific questions do you aim to answer or problems do you intend to solve? Establishing clear research goals will guide your topic selection process and keep your project focused.
• Consider Resources and Constraints: Take into account the resources, expertise, and time available for your research. Choose topics that are feasible within your constraints and align with your available resources. Balancing ambition with practicality is essential for successful research endeavors.
• Brainstorm and Narrow Down Options: Generate a list of potential research topics through brainstorming and exploration. Narrow down your options based on criteria such as relevance, feasibility, and alignment with your interests and goals. Choose the most promising topics that offer ample opportunities for exploration and discovery.
• Seek Feedback and Refinement: Once you’ve identified potential research topics, seek feedback from colleagues, advisors, or experts in the field. Refine your ideas based on their input and suggestions. Iteratively refining your topic selection process will lead to a more robust and well-defined research proposal.
• Stay Flexible and Open-Minded: Remain open to new ideas and opportunities as you progress through the research process. Be willing to adjust your research topic or direction based on new insights, challenges, or discoveries. Flexibility and adaptability are key qualities for successful research endeavors in mechanical engineering.

By following these steps and considering various factors, you can effectively select mechanical engineering research topics that align with your interests, goals, and the needs of the field.

Top 50 Mechanical Engineering Research Topics For Beginners

• Analysis of the efficiency of different heat exchanger designs.
• Optimization of airfoil shapes for enhanced aerodynamic performance.
• Investigation of renewable energy harvesting using piezoelectric materials.
• Development of smart materials for adaptive structures in aerospace applications.
• Study of vibration damping techniques for improving vehicle ride comfort.
• Design and optimization of suspension systems for off-road vehicles.
• Analysis of fluid flow characteristics in microchannels for cooling electronics.
• Evaluation of the performance of different brake systems in automotive vehicles.
• Development of lightweight materials for automotive and aerospace industries.
• Investigation of the effects of friction stir welding parameters on joint properties.
• Design and testing of a small-scale wind turbine for rural electrification.
• Study of the dynamics of flexible multibody systems in robotics.
• Development of a low-cost prosthetic limb using 3D printing technology.
• Analysis of heat transfer in electronic packaging for thermal management.
• Investigation of energy harvesting from vehicle suspension systems.
• Design and optimization of heat sinks for electronic cooling applications.
• Study of material degradation in composite structures under various loading conditions.
• Development of bio-inspired robotic mechanisms for locomotion.
• Investigation of the performance of regenerative braking systems in electric vehicles.
• Design and analysis of an autonomous agricultural robot for crop monitoring.
• Optimization of gas turbine blade profiles for improved efficiency.
• Study of the aerodynamics of animal-inspired flying robots (bio-drones).
• Development of advanced control algorithms for robotic manipulators.
• Analysis of wear mechanisms in mechanical components under different operating conditions.
• Investigation of the efficiency of solar water heating systems.
• Design and optimization of microfluidic devices for biomedical applications.
• Study of the effects of additive manufacturing parameters on part quality.
• Development of assistive devices for individuals with disabilities.
• Analysis of the performance of different types of bearings in rotating machinery.
• Investigation of the feasibility of using shape memory alloys in actuator systems.
• Design and optimization of a compact heat exchanger for space applications.
• Study of the effects of surface roughness on friction and wear in sliding contacts.
• Development of energy-efficient HVAC systems for buildings.
• Analysis of the performance of different types of fuel cells for power generation.
• Investigation of the feasibility of using biofuels in internal combustion engines.
• Design and testing of a micro-scale combustion engine for portable power generation.
• Study of the mechanics of soft materials for biomedical applications.
• Development of exoskeletons for rehabilitation and assistance in mobility.
• Analysis of the effects of vehicle aerodynamics on fuel consumption.
• Investigation of the potential of ocean wave energy harvesting technologies.
• Design and optimization of energy-efficient refrigeration systems.
• Study of the dynamics of flexible structures subjected to dynamic loads.
• Development of sensors and actuators for structural health monitoring.
• Analysis of the performance of different cooling techniques in electronics.
• Investigation of the potential of hydrogen fuel cells for automotive applications.
• Design and testing of a small-scale hydroelectric power generator.
• Study of the mechanics of cellular materials for impact absorption.
• Development of unmanned aerial vehicles (drones) for environmental monitoring.
• Analysis of the efficiency of different propulsion systems in space exploration.
• Investigation of the potential of micro-scale energy harvesting technologies for powering wireless sensors.

Top 50 Mechanical Engineering Research Topics For Intermediate

• Optimization of heat exchanger designs for enhanced energy efficiency.
• Investigating the effects of surface roughness on fluid flow in microchannels.
• Development of lightweight materials for automotive applications.
• Modeling and simulation of combustion processes in internal combustion engines.
• Design and analysis of novel wind turbine blade configurations.
• Study of advanced control strategies for unmanned aerial vehicles (UAVs).
• Analysis of wear and friction in mechanical components under varying operating conditions.
• Investigation of thermal management techniques for high-power electronic devices.
• Development of smart materials for shape memory alloys in actuator applications.
• Design and fabrication of microelectromechanical systems (MEMS) for biomedical applications.
• Optimization of additive manufacturing processes for metal 3D printing.
• Study of fluid-structure interaction in flexible marine structures.
• Analysis of fatigue behavior in composite materials for aerospace applications.
• Development of energy harvesting technologies for sustainable power generation.
• Investigation of bio-inspired robotics for locomotion in challenging environments.
• Study of human factors in the design of ergonomic workstations.
• Design and control of soft robots for delicate manipulation tasks.
• Development of advanced sensor technologies for condition monitoring in rotating machinery.
• Analysis of aerodynamic performance in hypersonic flight vehicles.
• Study of regenerative braking systems for electric vehicles.
• Optimization of cooling systems for high-performance computing (HPC) applications.
• Investigation of fluid dynamics in microfluidic devices for lab-on-a-chip applications.
• Design and optimization of passive and active vibration control systems.
• Analysis of heat transfer mechanisms in nanofluids for thermal management.
• Development of energy-efficient HVAC (heating, ventilation, and air conditioning) systems.
• Study of biomimetic design principles for robotic grippers and manipulators.
• Investigation of hydrodynamic performance in marine propeller designs.
• Development of autonomous agricultural robots for precision farming.
• Analysis of wind-induced vibrations in tall buildings and bridges.
• Optimization of material properties for additive manufacturing of aerospace components.
• Study of renewable energy integration in smart grid systems.
• Investigation of fracture mechanics in brittle materials for structural integrity assessment.
• Development of wearable sensors for human motion tracking and biomechanical analysis.
• Analysis of combustion instability in gas turbine engines.
• Optimization of thermal insulation materials for building energy efficiency.
• Study of fluid-structure interaction in flexible wing designs for unmanned aerial vehicles.
• Investigation of heat transfer enhancement techniques in heat exchanger surfaces.
• Development of microscale actuators for micro-robotic systems.
• Analysis of energy storage technologies for grid-scale applications.
• Optimization of manufacturing processes for lightweight automotive structures.
• Study of tribological behavior in lubricated mechanical systems.
• Investigation of fault detection and diagnosis techniques for industrial machinery.
• Development of biodegradable materials for sustainable packaging applications.
• Analysis of heat transfer in porous media for thermal energy storage.
• Optimization of control strategies for robotic manipulation tasks in uncertain environments.
• Study of fluid dynamics in fuel cell systems for renewable energy conversion.
• Investigation of fatigue crack propagation in metallic alloys.
• Development of energy-efficient propulsion systems for unmanned underwater vehicles (UUVs).
• Analysis of airflow patterns in natural ventilation systems for buildings.
• Optimization of material selection for additive manufacturing of biomedical implants.

Top 50 Mechanical Engineering Research Topics For Advanced

• Development of advanced materials for high-temperature applications
• Optimization of heat exchanger design using computational fluid dynamics (CFD)
• Control strategies for enhancing the performance of micro-scale heat transfer devices
• Multi-physics modeling and simulation of thermoelastic damping in MEMS/NEMS devices
• Design and analysis of next-generation turbofan engines for aircraft propulsion
• Investigation of advanced cooling techniques for electronic devices in harsh environments
• Development of novel nanomaterials for efficient energy conversion and storage
• Optimization of piezoelectric energy harvesting systems for powering wireless sensor networks
• Investigation of microscale heat transfer phenomena in advanced cooling technologies
• Design and optimization of advanced composite materials for aerospace applications
• Development of bio-inspired materials for impact-resistant structures
• Exploration of advanced manufacturing techniques for producing complex geometries in aerospace components
• Integration of artificial intelligence algorithms for predictive maintenance in rotating machinery
• Design and optimization of advanced robotics systems for industrial automation
• Investigation of friction and wear behavior in advanced lubricants for high-speed applications
• Development of smart materials for adaptive structures and morphing aircraft wings
• Exploration of advanced control strategies for active vibration damping in mechanical systems
• Design and analysis of advanced wind turbine blade designs for improved energy capture
• Investigation of thermal management solutions for electric vehicle batteries
• Development of advanced sensors for real-time monitoring of structural health in civil infrastructure
• Optimization of additive manufacturing processes for producing high-performance metallic components
• Investigation of advanced corrosion-resistant coatings for marine applications
• Design and analysis of advanced hydraulic systems for heavy-duty machinery
• Exploration of advanced filtration technologies for water purification and wastewater treatment
• Development of advanced prosthetic limbs with biomimetic functionalities
• Investigation of microscale fluid flow phenomena in lab-on-a-chip devices for medical diagnostics
• Optimization of heat transfer in microscale heat exchangers for cooling electronics
• Development of advanced energy-efficient HVAC systems for buildings
• Exploration of advanced propulsion systems for space exploration missions
• Investigation of advanced control algorithms for autonomous vehicles in complex environments
• Development of advanced surgical robots for minimally invasive procedures
• Optimization of advanced suspension systems for improving vehicle ride comfort and handling
• Investigation of advanced materials for 3D printing in aerospace manufacturing
• Development of advanced thermal barrier coatings for gas turbine engines
• Exploration of advanced wear-resistant coatings for cutting tools in machining applications
• Investigation of advanced nanofluids for enhanced heat transfer in cooling applications
• Development of advanced biomaterials for tissue engineering and regenerative medicine
• Exploration of advanced actuators for soft robotics applications
• Investigation of advanced energy storage systems for grid-scale applications
• Development of advanced rehabilitation devices for individuals with mobility impairments
• Exploration of advanced materials for earthquake-resistant building structures
• Investigation of advanced aerodynamic concepts for reducing drag and improving fuel efficiency in vehicles
• Development of advanced microelectromechanical systems (MEMS) for biomedical applications
• Exploration of advanced control strategies for unmanned aerial vehicles (UAVs)
• Investigation of advanced materials for lightweight armor systems
• Development of advanced prosthetic interfaces for improving user comfort and functionality
• Exploration of advanced algorithms for autonomous navigation of underwater vehicles
• Investigation of advanced sensors for detecting and monitoring air pollution
• Development of advanced energy harvesting systems for powering wireless sensor networks
• Exploration of advanced concepts for next-generation space propulsion systems.

Mechanical engineering research encompasses a wide range of topics, from fundamental principles to cutting-edge technologies and interdisciplinary applications. By choosing the right mechanical engineering research topics and addressing key challenges, researchers can contribute to advancements in various industries and address pressing global issues. As we look to the future, the possibilities for innovation and discovery in mechanical engineering are endless, offering exciting opportunities to shape a better world for generations to come.

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Digital Commons @ USF > College of Engineering > Mechanical Engineering > Theses and Dissertations

Mechanical Engineering Theses and Dissertations

Theses/dissertations from 2023 2023.

Metachronal Locomotion: Swimming, Scaling, and Schooling , Kuvvat Garayev

A Human-in-the-Loop Robot Grasping System with Grasp Quality Refinement , Tian Tan

Theses/Dissertations from 2022 2022

Health Effects of Oil Spills and Dispersal of Oil Droplets and Zooplankton by Langmuir Cells , Sanjib Gurung

Estimating the As-Placed Grout Volume of Auger Cast Piles , Tristen Mee

Hybrid RANS-LES Hemolytic Power Law Modeling of the FDA Blood Pump , Joseph Tarriela

Theses/Dissertations from 2021 2021

Dynamic Loading Directed Neural Stem Cell Differentiation , Abdullah Revaha Akdemir

An Investigation of Cross-links on Crystallization and Degradation in a Novel, PhotoCross-linkable Poly (Lactic Acid) System , Nicholas Baksh

A Framework to Aid Decision Making for Smart Manufacturing Technologies in Small-and Medium-Sized Enterprises , Purvee Bhatia

Formation of Gas Jets and Vortex Rings from Bursting Bubbles: Visualization, Kinematics, and Fluid Dynamics , Ali A. Dasouqi

Development of Carbon and Silicon Carbide Based Microelectrode Implantable Neural Interfaces , Chenyin Feng

Sulfate Optimization in the Cement-Slag Blended System Based on Calorimetry and Strength Studies , Mustafa Fincan

Interrelation of Thermal Stimulation with Haptic Perception, Emotion, and Memory , Mehdi Hojatmadani

Modeling the Ambient Conditions of a Manufacturing Environment Using Computational Fluid Dynamics (CFD) , Yang Liu

Flow Visualization and Aerosol Characterization of Respiratory Jets Exhaled from a Mannequin Simulator , Sindhu Reddy Mutra

A Constitutive-Based Deep Learning Model for the Identification of Active Contraction Parameters of the Left Ventricular Myocardium , Igor Augusto Paschoalotte Nobrega

Sensible/Latent Hybrid Thermal Energy Storage for the Supercritical Carbon Dioxide Brayton Cycle , Kelly Osterman

Evaluating the Performance of Devices Engineering to Quantify the FARS Test , Harsh Patel

Event-Triggered Control Architectures for Scheduling Information Exchange in Uncertain and Multiagent Systems , Stefan Ristevski

Theses/Dissertations from 2020 2020

Experimental Investigation of Liquid Height Estimation and Simulation Verification of Bolt Tension Quantification Using Surface Acoustic Waves , Hani Alhazmi

Investigation of Navigation Systems for Size, Cost, and Mass Constrained Satellites , Omar Awad

Simulation and Verification of Phase Change Materials for Thermal Energy Storage , Marwan Mosubah Belaed

Control of a Human Arm Robotic Unit Using Augmented Reality and Optimized Kinematics , Carlo Canezo

Manipulation and Patterning of Mammalian Cells Using Vibrations and Acoustic Forces , Joel Cooper

Stable Adaptive Control Systems in the Presence of Unmodeled and Actuator Dynamics , Kadriye Merve Dogan

The Design and Development of a Wrist-Hand Orthosis , Amber Gatto

ROBOAT - Rescue Operations Bot Operating in All Terrains , Akshay Gulhane

Mitigation of Electromigration in Metal Interconnects Passivated by Ångstrom-Thin 2D Materials , Yunjo Jeong

Swimming of Pelagic Snails: Kinematics and Fluid Dynamics , Ferhat Karakas

Functional Gait Asymmetries Achieved Through Modeling and Understanding the Interaction of Multiple Gait Modulations , Fatemeh Rasouli

Distributed Control of Multiagent Systems under Heterogeneity , Selahattin Burak Sarsilmaz

Design and Implementation of Intuitive Human-robot Teleoperation Interfaces , Lei Wu

Laser Micropatterning Effects on Corrosion Resistance of Pure Magnesium Surfaces , Yahya Efe Yayoglu

Theses/Dissertations from 2019 2019

Synthesis and Characterization of Molybdenum Disulfide/Conducting Polymer Nanocomposite Materials for Supercapacitor Applications , Turki S. Alamro

Design of Shape-Morphing Structures Consisting of Bistable Compliant Mechanisms , Rami Alfattani

Low Temperature Multi Effects Desalination-Mechanical Vapor Compression Powered by Supercritical Organic Rankine Cycle , Eydhah Almatrafi

Experimental Results of a Model Reference Adaptive Control Approach on an Interconnected Uncertain Dynamical System , Kemberly Cespedes

Modeling of Buildings with Electrochromic Windows and Thermochromic Roofs , Hua-Ting Kao

Design and Testing of Experimental Langmuir Turbulence Facilities , Zongze Li

Solar Thermal Geothermal Hybrid System With a Bottoming Supercritical Organic Rankine Cycle , Francesca Moloney

Design and Testing of a Reciprocating Wind Harvester , Ahmet Topcuoglu

Distributed Spatiotemporal Control and Dynamic Information Fusion for Multiagent Systems , Dzung Minh Duc Tran

Controlled Wetting Using Ultrasonic Vibration , Matthew A. Trapuzzano

On Distributed Control of Multiagent Systems under Adverse Conditions , Emre Yildirim

Theses/Dissertations from 2018 2018

Synthesis and Characterization of Alpha-Hematite Nanomaterials for Water-Splitting Applications , Hussein Alrobei

Control of Uncertain Dynamical Systems with Spatial and Temporal Constraints , Ehsan Arabi

Simulation and Optimization of a Sheathless Size-Based Acoustic Particle Separator , Shivaraman Asoda

Simulation of Radiation Flux from Thermal Fluid in Origami Tubes , Robert R. Bebeau

Toward Verifiable Adaptive Control Systems: High-Performance and Robust Architectures , Benjamin Charles Gruenwald

Developing Motion Platform Dynamics for Studying Biomechanical Responses During Exercise for Human Spaceflight Applications , Kaitlin Lostroscio

Design and Testing of a Linear Compliant Mechanism with Adjustable Force Output , William Niemeier

Investigation of Thermal History in Large Area Projection Sintering, an Additive Manufacturing Technology , Justin Nussbaum

Acoustic Source Localization with a VTOL sUAV Deployable Module , Kory Olney

Defect Detection in Additive Manufacturing Utilizing Long Pulse Thermography , James Pierce

Design and Testing of a Passive Prosthetic Ankle Foot Optimized to Mimic an Able-Bodied Gait , Millicent Schlafly

Simulation of Turbulent Air Jet Impingement for Commercial Cooking Applications , Shantanu S. Shevade

Materials and Methods to Fabricate Porous Structures Using Additive Manufacturing Techniques , Mohsen Ziaee

Theses/Dissertations from 2017 2017

Large Area Sintering Test Platform Design and Preliminary Study on Cross Sectional Resolution , Christopher J. Gardiner

Enhanced Visible Light Photocatalytic Remediation of Organics in Water Using Zinc Oxide and Titanium Oxide Nanostructures , Srikanth Gunti

Heat Flux Modeling of Asymmetrically Heated and Cooled Thermal Stimuli , Matthew Hardy

Simulation of Hemiparetic Function Using a Knee Orthosis with Variable Impedance and a Proprioception Interference Apparatus , Christina-Anne Kathleen Lahiff

Synthesis, Characterization, and Application of Molybdenum Oxide Nanomaterials , Michael S. McCrory

Effects of Microstructure and Alloy Concentration on the Corrosion and Tribocorrosion Resistance of Al-Mn and WE43 Mg Alloys , Hesham Y. Saleh Mraied

Novel Transducer Calibration and Simulation Verification of Polydimethylsiloxane (PDMS) Channels on Acoustic Microfluidic Devices , Scott T. Padilla

Force Compensation and Recreation Accuracy in Humans , Benjamin Rigsby

Experimental Evaluation of Cooling Effectiveness and Water Conservation in a Poultry House Using Flow Blurring ® Atomizers , Rafael M. Rodriguez

Media Velocity Considerations in Pleated Air Filtration , Frederik Carl Schousboe

Orthoplanar Spring Based Compliant Force/Torque Sensor for Robot Force Control , Jerry West

Experimental Study of High-Temperature Range Latent Heat Thermal Energy Storage , Chatura Wickramaratne

Theses/Dissertations from 2016 2016

Al/Ti Nanostructured Multilayers: from Mechanical, Tribological, to Corrosion Properties , Sina Izadi

Molybdenum Disulfide-Conducting Polymer Composite Structures for Electrochemical Biosensor Applications , Hongxiang Jia

Waterproofing Shape-Changing Mechanisms Using Origami Engineering; Also a Mechanical Property Evaluation Approach for Rapid Prototyping , Andrew Jason Katz

Hydrogen Effects on X80 Steel Mechanical Properties Measured by Tensile and Impact Testing , Xuan Li

Application and Analysis of Asymmetrical Hot and Cold Stimuli , Ahmad Manasrah

Droplet-based Mechanical Actuator Utilizing Electrowetting Effect , Qi Ni

Experimental and Computational Study on Fracture Mechanics of Multilayered Structures , Hai Thanh Tran

Designing the Haptic Interface for Morse Code , Michael Walker

Optimization and Characterization of Integrated Microfluidic Surface Acoustic Wave Sensors and Transducers , Tao Wang

Corrosion Characteristics of Magnesium under Varying Surface Roughness Conditions , Yahya Efe Yayoglu

Theses/Dissertations from 2015 2015

Carbon Dioxide (CO 2 ) Emissions, Human Energy, and Cultural Perceptions Associated with Traditional and Improved Methods of Shea Butter Processing in Ghana, West Africa , Emily Adams

Experimental Investigation of Encapsulated Phase Change Materials for Thermal Energy Storage , Tanvir E. Alam

Design Of Shape Morphing Structures Using Bistable Elements , Ahmad Alqasimi

Heat Transfer Analysis of Slot Jet Impingement onto Roughened Surfaces , Rashid Ali Alshatti

Systems Approach to Producing Electrospun Polyvinylidene Difluoride Fiber Webs with Controlled Fiber Structure and Functionality , Brian D. Bell

Self-Assembly Kinetics of Microscale Components: A Parametric Evaluation , Jose Miguel Carballo

Measuring Polydimethylsiloxane (PDMS) Mechanical Properties Using Flat Punch Nanoindentation Focusing on Obtaining Full Contact , Federico De Paoli

A Numerical and Experimental Investigation of Flow Induced Noise In Hydraulic Counterbalance Valves , Mutasim Mohamed Elsheikh

An Experimental Study on Passive Dynamic Walking , Philip Andrew Hatzitheodorou

Use of Anaerobic Adhesive for Prevailing Torque Locking Feature on Threaded Product , Alan Hernandez

Viability of Bismuth as a Green Substitute for Lead in Jacketed .357 Magnum Revolver Bullets , Joel A. Jenkins

A Planar Pseudo-Rigid-Body Model for Cantilevers Experiencing Combined Endpoint Forces and Uniformly Distributed Loads Acting in Parallel , Philip James Logan

Kinematic Control of Redundant Mobile Manipulators , Mustafa Mashali

Passive Symmetry in Dynamic Systems and Walking , Haris Muratagic

Mechanical Properties of Laser-Sintered-Nylon Diamond Lattices , Clayton Neff

Design, Fabrication and Analysis of a Paver Machine Push Bar Mechanism , Mahendra Palnati

Synthesis, Characterization, and Electrochemical Properties of Polyaniline Thin Films , Soukaina Rami

A Technical and Economic Comparative Analysis of Sensible and Latent Heat Packed Bed Storage Systems for Concentrating Solar Thermal Power Plants , Jamie Trahan

Use of FDM Components for Ion Beam and Vacuum Applications , Eric Miguel Tridas

The Development of an Adaptive Driving Simulator , Sarah Marie Tudor

Dual 7-Degree-of-Freedom Robotic Arm Remote Teleoperation Using Haptic Devices , Yu-Cheng Wang

Ductility and Use of Titanium Alloy and Stainless Steel Aerospace Fasteners , Jarrod Talbott Whittaker

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Thesis Proposal

Note: This article is partially based on the 2017-2018 MechE Graduate Student Guide (PDF) . Please check the latest guide for the most-up to date formatting requirements.

Criteria for Success

A strong thesis proposal…

• Motivates your project and introduces your audience to the state-of-the-art for the problem you’re working on.
• Explains the limitations in the current methods through literature review and/or original analysis. This should also explain why the limitations matter and why they’re the right ones to focus on.
• Clearly explains your technical approach to make specific improvements to some part of the field.
• Uses original analysis and literature to support the feasibility of the approach.
• Describes what is original about your work.
• Provides a practical outline for completing this research : a degree timeline laying out quantifiable hypotheses, experimental/numerical/theoretical techniques, and metrics for evaluation .

Structure Diagram

Meche-specific structure requirements.

Your thesis proposal should be limited to 6 pages including figures and references.

In addition, you need a cover page that (only) includes:

• tentative title of the thesis
• brief abstract
• committee chair and/or advisor should be indicated
• include their official titles, departmental affiliations, and email addresses

The purpose of your thesis proposal is to introduce your research plan to your thesis committee. You want the committee members to come away understanding what your research will accomplish, why it is needed ( motivation ), how you will do it ( feasibility & approach ), and most importantly, why it is worthy of a PhD ( significance ).

You intend to solve a real and important problem, and you are willing to dedicate years of your life to it, so use your proposal to get the committee excited about your research!

Analyze your audience

Unlike many of the papers and presentations you will write during graduate school, only a select few people will read your thesis proposal. This group will always include your PhD committee and your research advisor, and may include other interested MechE faculty or scientists and engineers at your funding source.

Therefore, you will typically have a good understanding of your audience before it is written. This can allow you to tailor your message to the technical level of your specific audience. If you aren’t sure what your audience could reasonably be expected to know, be conservative! Regardless, your audience is always looking to answer the questions: “ what is this research, how will you perform it, and why does it matter?”

While the small audience may make you less interested in committing time to your proposal, the exercise of motivating and justifying your work plan will be critical to your PhD.

Follow the standard structure for research proposals

While some variation is acceptable, don’t stray too far from the following structure. See also the Structure Diagram above.

• Introduction . Provide only the necessary information to motivate your research, and show how it fits into the broader field. What is the problem you are trying to solve? By the end of the introduction, your audience should understand the basics of what you will do and why you will do it.
• Background/Methodology . Describe the current state of the art and related research fields in sufficient technical detail. The goal is provide just enough detail to give the reader a sound understanding of the limitations and the need for new work. Do not go into detail that does not directly help in understanding your You are not trying to make your reader understand everything about the topic or demonstrate how much you know.
• Objectives . Although not strictly necessary, this section lets you summarize concrete goals of your work, and can help to serve as a checklist for yourself as you move through the process. This is best for projects that tackle many interrelated problems. Think of this as a list of concrete (quantifiable) goals that you want to accomplish.
• Proposed Work. Explain how your work will solve the problems that you have identified. How will you address the objectives above? Provide just enough technical specificity to leave the reader with a firm grasp of what you will do.
• Provide a set of time-structured goals and deliverables. While this is not strictly necessary, your committee will want a timeline when you meet with them, so it can help to start planning now. You want to graduate, so make sure that you have a plan to do so!
• This is a standard section listing references in an appropriate format (MLA, APA, etc.)

Consider the logical sequence of your sections. After the introduction, your audience should be intrigued by a key problem, and intrigued that you know how to solve it. Through the background, they learn that this problem is more difficult than they originally realized. Finally, in the proposed work they learn that your proposal addresses the additional complexity introduced in the background, and they have confidence that you can actually solve the problem.

Summarize the current research field

You need to have a strong grasp of the broader research community. How can you contribute, if you don’t know what is done and what needs to be done?

The point here is not to educate your audience, but rather to provide them with the tools needed to understand your proposal. A common mistake is to explain all of the research that you did to understand your topic and to demonstrate that you really know your field. This will bore your audience, who either already knows this information or does not see why they should care. It’s more important to show where current gaps are. Cut anything that doesn’t answer the what and why of what people are doing. Your depth of knowledge will come through in your thoughtful proposal.

Justify the significance of your work

Answer the question: “What happens if your work is successful?” Again, you are trying to convince your readers either to give you funding or to work with you for three (or more) years. Convince them that your project is worth it.

Your research doesn’t have to revolutionize your field, but you need to explain concretely how it will move your field forward. For example, “Successful development of the proposed model will enable high-fidelity simulation of boiling” is a specific and convincing motivation, compared to, “The field of boiling modeling must be transformed in order to advance research.”

Justify your research plan

Identify the steps needed to overcome your identified problem/limitation. Though your PhD will evolve over time, the tasks and timeline that you identify in your proposal will continue to help determine the trajectory of your research. A good plan now can save a lot of work a few years down the road.

A strong research plan answers three key questions:

• g., “In order to engineer material properties using mesoscopic defects, it is necessary to characterize the defects, measure how they affect material response, and identify techniques to reproducibly create the defects at specific sites within a material.”
• g., “In my PhD, I will focus on developing high-speed dynamic imaging techniques to characterize transient defect states in metallic nanowires. I will then use these techniques to measure the properties of nanowires fabricated with three different processes known to produce different defect structures.”
• How will you evaluate success in each step? These metrics should be concrete and measurable! Putting the thought into metrics now will make it easier for your committee (and yourself) to check a box and say ‘you can graduate.’

Each of these questions should be supported by details that reflect the current state of the art. Technical justification is critical to establish credibility for your plan. Reference the material that you introduced in the background section. You should even use your research plan to tailor your background section so that your committee knows just enough to believe what you’re claiming in your plan.

Based on the tasks and metrics in your plan, establish specific reflection points when you’ll revisit the scope of your project and evaluate if changes are needed.

Include alternative approaches

You won’t be able to predict all of the challenges you will encounter, but planning alternative approaches early on for major methods or decision points will prepare you to make better game-time decisions when you come up against obstacles. e.g.,

I will develop multi-pulse, femtosecond illumination for high speed imaging following Someone et al. Based on the results they have shown, I expect to be able to observe defect dynamics with micron spatial resolution and microsecond temporal resolution. If these resolutions are not achievable in the nanowire systems, I will explore static measurement techniques based on the work of SomeoneElse et al.

Resources and Annotated Examples

Annotated example 1.

This is a recent MechE thesis proposal, written in the style of an IEEE paper. 1,022 KB

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Mechanical Engineering Thesis

• 1 Introduction to mechanical engineering thesis
• 2 Sample mechanical engineering thesis topics and files
• 3 What are the Learning Outcomes for a Mechanical Engineering Thesis?
• 4.1.1 Design, Build and Test or Experimental Mechanical Engineering Thesis
• 4.1.2 Modelling Of an Engineering Process
• 4.1.3 Detailed Design of An Engineering System
• 4.1.4 Preparation And Testing of Computer Software
• 4.2 Theoretical or Research Oriented Mechanical Engineering Final Year Projects
• 5.1 Mechanical Engineering Thesis from The Published List of Project Topics Provided by The Members of Academic Staff
• 5.2 Mechanical Engineering Thesis Topic from A Student’s Own Idea
• 5.3 Mechanical Engineering Thesis Topic from A Sponsoring Company
• 6.1.1 Risk Assessment for An Engineering Thesis Proposal
• 6.1.2 Project Timeline/Plan for A Mechanical Engineering Thesis
• 6.1.3 Ethics Assessment for A Mechanical Engineering Thesis
• 6.2 Mechanical Engineering Thesis Interim Report or Progression Report
• 6.3 Mechanical Engineering Dissertation Final Report
• 6.4 PowerPoint Presentation (Slides or Poster)
• 6.5 Oral Presentation/Examination (Viva) of Your Mechanical Engineering Thesis
• 7 Structure Or Format of The Mechanical Engineering Thesis Final Report
• 8 Why choose topengineeringsolutions.com for your mechanical engineering thesis?
• 9 Conclusion

Introduction to mechanical engineering thesis

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Sample mechanical engineering thesis topics and files

In this section you, will find a list of mechanical engineering thesis topics you can select from. Some of the topics have a sample report and all the relevant files (report, 3D CAD files, simulation files, codes etc). Follow the link provided on the topic to access the materials. The sample report and project files will make your work very easy when working on your mechanical engineering thesis. You can still request a custom/new mechanical engineering thesis report for your selected topic. If you are interested in a topic that does not have a sample report and all the project materials, place an order for a custom report and we will be glad to help. We can also help you identify a mechanical engineering thesis title in your area of interest or advise you on the suitability of your selected mechanical engineering final year project title.

What are the Learning Outcomes for a Mechanical Engineering Thesis?

The engineering final year project is an opportunity for students to demonstrate their ability to independently carry out a substantial project from specification through to completion. It helps the student develop and practice many of the attributes required of a modern

professional engineer including project planning, project management and presentation of

progress and results. A mechanical engineering thesis is meant to help you demonstrate the ability to do the following:

• Plan a substantial project
• Carry out preliminary study
• Organise the acquisition of necessary equipment and components
• Liaise with staff and other students
• Set a number of targets
• Work independently to attain the targets
• Communicate progress with a supervisor
• Reorganise plan to accommodate unforeseen problems
• Complete the work in time
• Present an oral and written report of the work

Types of mechanical engineering dissertation/thesis

Mechanical engineering final year projects can be classified into various categories depending on how you obtain your research data. The two main categories of mechanical engineering final year projects are practical mechanical engineering final year projects and theoretical mechanical engineering final year projects.

Practical mechanical engineering thesis

In a practical mechanical engineering dissertation, the student relies on primary research, that is, you obtain the data yourself. A practical mechanical engineering final year project can further be classified as “Design, build and test or experimental ” projects, modelling of an engineering process, Detailed design of an engineering system and preparation and testing of computer software.

Design, Build and Test or Experimental Mechanical Engineering Thesis

This type of mechanical engineering final year project involves designing a physical engineering component, building a prototype and thereafter testing it. This is the most intensive and time-consuming type of mechanical engineering final year project. It requires excellent time management skills and discipline in order to complete it successfully. You need to start early to avoid late submission or submitting incomplete work. Before you decide on this type of engineering thesis, ascertain the availability and accessibility of experimental equipment and work space.  

Although experimental mechanical engineering final year projects are intensive, they will impart you with lots of engineering technical skills which include assessing project requirements and creating product design specifications, using computer-aided design/modelling software, using various engineering equipment to manufacture an engineering product, liaising with suppliers to source for materials, producing and implementing designs and test procedures, testing, evaluating, modifying and re-testing products, analysing and interpreting data; writing reports and documentation among others. Sample experimental mechanical engineering final year projects are given here .

Modelling Of an Engineering Process

Mechanical engineering thesis types that involve modelling of an engineering process are mainly focused on improving and optimising manufacturing processes by applying numerical simulation tools hence achieving better products with regard to process selection, material selection, geometry among others. Typical manufacturing processes that can be modelled include 3D printing (additive manufacturing), casting and composites manufacturing etc. An example of such a mechanical engineering dissertation could be application of lean manufacturing concepts to a specific engineering process in order to build quality in the manufactured product while at the same time eliminating wastes. This mechanical engineering final year project type is interdisciplinary as it applies multiple concepts such as process technology, fluid mechanics, solid mechanics, materials science and thermodynamics etc.

Detailed Design of An Engineering System

Mechanical engineering final year projects involving design of an engineering system aim at applying mechanical engineering principles to design complex engineering systems that are reliable, cost-effective, efficient and with minimum environmental impacts. For example, the project may entail applying principles of thermodynamics and heat transfer in the design of advanced energy conversion systems for power generation or designing an optimised heat exchanger for a certain application. This mechanical engineering thesis type requires the student to clearly state the function of the system (what the system can fulfil e.g., system to harness both thermal and electrical energy from solar (solar PVT), provide system specifications and have a clear evaluation criterion. Evaluation criteria are the design objectives meant to minimise limitations of the engineering system while at the same time increasing the system benefits.

Preparation And Testing of Computer Software

This type of mechanical engineering dissertation entails developing and testing a custom computer software which can be used as a teaching aid, for simulation and engineering analysis or for computer aided design. It may also involve creating Machine Learning (ML) algorithms for predicting engineering processes and behaviour. Examples of mechanical engineering thesis that involve preparation and testing of computer software are given in this article.

Theoretical or Research Oriented Mechanical Engineering Final Year Projects

A theoretical mechanical engineering dissertation focuses on secondary research or literature review. In this case, you review relevant published scholarly sources such as peer reviewed journal articles, previous mechanical engineering dissertations and use the findings in those sources to make a conclusion about a specific engineering issue. You can decide to compare and contrast research by other authors in order to establish gaps for future study or apply their findings to a practical situation.

How to select a mechanical engineering thesis topic

Selecting your mechanical engineering dissertation topic is an important task that you must undertake before working on your final year project. As discussed above, a mechanical engineering thesis may be practical, theoretical or a combination of both. In all cases, before selecting the thesis topic, careful consideration should be given crucial factors like relevance of the topic to mechanical engineering course coverage, complexity of the problem to be undertaken, your interests and career aspirations, and the availability of a willing supervisor. It is worth noting that although proper final year project selection may not guarantee high marks, it certainly increases the probability of success in your project. If you need help in selecting your mechanical engineering thesis topic, you can check sample projects here or contact us. Mechanical engineering final year project selection may be in one of the following ways:

Mechanical Engineering Thesis from The Published List of Project Topics Provided by The Members of Academic Staff

In most institutions, university academic staff propose projects to reflect their consultancy, research, teaching or laboratory development interest. The project titles are compiled and published for students to choose from. Each topic on the list usually has a brief summary of what the project entails and the contact details of the supervisor who suggested the topic. If you are interested in any of the suggested thesis topics, it is upon you to contact the supervisor and get more information about it. The biggest advantage with this type of thesis topic selection is that in most cases, the other students will have worked on the same project in previous years. Thus, you will be able to identify challenges that they encountered and how they tackled them.   

Mechanical Engineering Thesis Topic from A Student’s Own Idea

You may propose a final year project based on your own specific interest or inventive talents. The issue problem you intend to tackle should be selected with great care. Whilst ideas for the engineering thesis may come in a flash of inspiration, it is more likely that you will already have a rough idea of what you want to do, based perhaps on your working experience (if any) or your daily activities. The easiest way to select a suitable engineering thesis topic that will guarantee success is to view a list of sample mechanical engineering dissertations that have been done in the past. A website like https://www.engineeringfinalprojects.com has a list of mechanical engineering final year projects that you can choose from. In addition, it gives you access to the sample final engineering thesis report for the selected topic as well as the relevant simulation files, 3D CAD models and codes that were used when completing the project. Having access to the final report and simulation files can make your work really simple and guarantee success in your project.

Mechanical Engineering Thesis Topic from A Sponsoring Company

Mechanical engineering thesis topics may also be provided by external companies and this is highly encouraged to increase industry relevance of the module. However, industry-generated projects may have some problems such as commercial security, difficulties of assessment and satisfactory liaison with the company among others. Nonetheless, if the project is carefully chosen and there is full commitment from both the company and the university, the problems are easily overcome.

Mechanical Engineering Final Year Project Deliverables

In order to ascertain the extent to which you have met the learning outcomes of the final year project module, you are assessed against various deliverables. There may be a slight variation between universities but the main deliverables are as outlined below:

Mechanical Engineering Project Proposal & Risk and Ethics Assessment/Plan Report/Scope

After submitting and obtaining approval for your project idea, you will be required to submit a project proposal. The name of this deliverable varies from one university to the other but the content is almost the same. In some cases, it is referred to a scope report, project plan report or simply proposal report. When submitting your mechanical engineering project proposal, you may also be required to submit a risk and ethics assessment form. A project proposal has an abstract which provide a clear and concise summary of the project proposal for a busy reader; an introduction chapter which includes motivation for undertaking the project, objectives of the project and significance of the project; the proposed approach (methodology); timeline or project plan; risk and ethics assessment; conclusion and references. Detailed explanation of what these chapters entail will be discussed in the project format section . However, risk assessment, project plan/timeline and ethics assessment are unique to this section and will be discussed here.

Risk Assessment for An Engineering Thesis Proposal

It is usually recommended and, in some cases, mandatory to provide a thorough assessment of the likely risks associated with the project. The risk assessment includes both risk for access to resource, general risks affecting the delivery of the project and health and safety. In this case, State the plausibility of each risk. Provide risk management strategies to eliminate or mitigate the risks discussed. Also, determine whether or not the proposed risk management strategies are plausible and reasonable. The general risk assessment procedure is as follows:

Step 1 – Identify the hazards and associated risks Divide the project into specific tasks. For each task, identify the hazards and associated risks. Step 2 – Identify the current risk treatments

Risk treatment is a process of implementing measures to reduce the risks associated with a hazard. In this step, you should identify the existing risk treatments that are in place to mitigate the identified risks.

Step 3 – Analyse and calculate the risk

In this step you are supposed to first consider the consequences of the identified risk, then consider the likelihood of the risk and finally calculate the risk.

Step 4 – Additional risk treatments and risk acceptance In this step, any additional risk treatments should be identified that will reduce the overall level of risk. The remaining level of risk (residual risk) should be of such a nature that the resulting level of likelihood and consequence are acceptable for the risk owner. A risk calculator or risk assessment template is provided here . You can download and use it for conducting risk assessment for your engineering thesis. Please note that risk assessment varies with the type of mechanical engineering final year project . A sample risk assessment for an experimental engineering thesis is given here. Also, a sample risk assessment for a theoretical or design-based mechanical engineering final year project is provided here. You can download and use them as guides. Please note that The Activity Overall Risk Rating must be LOW . Activities with an Overall Risk Rating of MODERATE or above must be accompanied by a Risk Management Plan. However, the risks must be reduced to As Low As Reasonably Practicable and the Risk Assessment must been reviewed and approved by the project supervisor.

Project Timeline/Plan for A Mechanical Engineering Thesis

When creating your engineering thesis timeline or plan, provide a clear description of a well thought out project timeline. The use of a Gantt chart is highly recommended. Determine whether or not the proposed timeline is realistic. Identify and discuss all items on the critical path. Note that this timeline covers the entire project in both semesters. A sample Gantt chart for a mechanical engineering thesis is attached. The most common tools for creating a professional engineering thesis Gantt chart include Microsoft Projects and Ganttproject . Ganttproject is free of charge, easy to use and is small in size.

Ethics Assessment for A Mechanical Engineering Thesis

You should address any ethic issues arising from your project work (this is required in all project reports). For students in UK universities, the engineering ethics are guided by four fundamental principles based on the Royal Academy of Engineering’s document “ Statement of Ethical Principles “. The principles are:

• Accuracy and Rigour
• Honesty and Integrity
• Respect for Life, Law and the Public Good
• Responsible Leadership: Listening and Informing

When carrying out ethics assessment, you should concentrate on the potential impact of your work , rather than your own honesty etc. Unless your project requires specific ethic approval, a typical ethics assessment is simply a general discussion relating to the project topic. Concentrate on the most relevant issues, rather than trying to find something to fit every possible point

Mechanical Engineering Thesis Interim Report or Progression Report

A mechanical engineering interim report which can also be known as mechanical engineering progress report is aimed at monitoring your project through the thesis. It is usually about 15 to 30 pages depending on your institution. The appropriate length of the report may also depend on the type of mechanical engineering thesis that you have selected. If you have any doubts or questions about the length please discuss this with your supervisor. Your progress report gives evidence of research and technical progress towards objectives as well as monitoring of the project plan and management of any adjustments to the project direction. By evaluating the interim report, the supervisor can keep track of what work you have completed and what is still to be completed, and identifying any weaknesses where further development may be needed. Your mechanical engineering thesis interim report is an early opportunity for your supervisor to assess your progress and to provide feedback. By the time you submit the interim report, you should, by now, have a clear idea in terms of what you are doing, why you are doing it, and how you are doing it. You should also bear in mind when writing your mechanical engineering thesis progress report that its purpose is to report the results obtained so far, and to show whether:

•  The stated project objectives are being met
• The project is proceeding on schedule
• You are managing the project in the best possible way
• There are any previously unforeseen problems that require attention.

In order to achieve the learning outcomes of the progress report, your report should state how far you have progressed with each of the activities that you planned, whether you are on schedule, and discuss any problems which you have encountered or can see in the future. Typical chapters of your mechanical engineering thesis progress report include abstract, Table of Contents, Introduction chapters (aim and objectives, motivation, and significance of the project), Background or Literature Review chapter, Proposed Approach chapter (methodology), Preliminary Results and Discussions, Conclusion, References and appendices (if any). By using the above chapters, the supervisor is able to verify what has been completed. It is also advisable to include a Gantt chart showing what work has been completed. If you have not completed activities scheduled to have been done you should say why not, and explain how you will fit the activity into your future work.

Mechanical Engineering Dissertation Final Report

The final thesis report is the single most important deliverable which must be submitted. Since the final report is relatively long, you should ensure that you start writing the report several weeks before the deadline. The exact structure of the report will vary according to the nature of your project but it must comply with the project handbook or guide which usually varies from one university to the other. Nonetheless, the main chapters of an engineering thesis final report are nearly the same. Before submitting the final copy of your engineering dissertation final report, you should check the following:

• Does the report have proper tenses, grammar, spelling, and punctuation?
• Are the project objectives clearly stated? Have they been fulfilled?
• Is the referencing well done and consistent throughout the report?
• Does the abstract give a clear idea of what has is in the Final Report?
• Is the literature review sufficient and relevant to the project? Does it indicate the current state-of-the-art?
• Is your methodology appropriate for the task? Is there any evidence in support of the methodology?
• Are any limitations of the study clearly presented?
• Are the results clearly presented?
• Are conclusions based on evidence? Have any claims been made which cannot be substantiated?

The appropriate length of the report is not straightforward. However, you project handbook/guide will have information on the expected length. Nonetheless, the length of an engineering thesis report depends to some extent on nature of the work. The report must be fit for purpose and optimised to be as effective as possible in the doing task for which it was created. In this case the task is to convey to the reader (marker) the work done on the project, placing it clearly in the context of the topic background, motivation and requirements. From the assessment point of view the aim is show to the marker the academic and technical competence of the student, demonstrating the project was conducted in a professional manner. The report should be written so that it can be read and absorbed by an engineer having a basic knowledge of the subject. An engineering thesis report will be regarded to be too short if it does not convey the learning outcomes for example, significant details on how the project was implemented were left out, or there was insufficient background to place the work in its proper context. On the other hand, an engineering dissertation report can be regarded as excessively large if it has too much detail, so that the reader is overburdened with unnecessary information or it contains irrelevant details. An excessively large final report may be penalised. Stick to the project handbook guidelines. If necessary, ask for advice from your supervisor on what details / level of detail to include in different areas.

PowerPoint Presentation (Slides or Poster)

Presentation which can be in the form of slides or poster gives students experience in preparing and presenting a concise oral description of their work with visual aids. Most universities provide the standard presentation template which must be used by all students. A well-prepared engineering final year project presentation provides a concise overview of your project. It should precisely deliver the essential elements of the project and should be laid out to make comprehension of the essential elements of the project straightforward. It should be attractive in the sense that it draws an audience to it and invites further questions. Try to make the poster as visually appealing and engaging as possible such that you grab the viewer’s interest. Ensure you include plenty of diagrams and figures/images and do not clutter your poster with too much text. It should demonstrate excellent content and technical achievement. The poster should be logically constructed and present content at the appropriate level. You will need to demonstrate that you have an in‐depth knowledge and understanding of your project. Also, do not presume that the majority of viewers will be specialists in your field, so try to provide sufficient background and explanation for them to follow your poster.

Your project presentation slides or poster should be typed in a clear bold print that can be easily read from distances of around 1 – 2 metres with the title displayed in a large font at the top of the poster. The chapter titles like Introduction or Background , Objectives , Methodology , Results and Conclusion(s) etc should be in bold and distinguishable. The size of the title and normal text will depend on poster size as stipulated in the Guidelines on Poster Presentation which are usually provided together with the project handbook. Use your own judgement. Do not use too large or too small font size. Avoid too much text. If you cannot fit everything you wish in, you need to assess the risks of using smaller font size. You may be able to put more information in it but will it aid your presentation? It advisable to use no more than 4 different colours, and try to match the main colour theme. In addition to the main content, you must include your project title, your name, student ID and name of your supervisor.

Oral Presentation/Examination (Viva) of Your Mechanical Engineering Thesis

In the oral presentation/examination (Viva) you will be asked questions by your assessor, supervisor and panel members. You will be assessed on the responses which you give to questions and the understanding which you demonstrate regarding your project and its content. When presenting, ensure that you appear confident and enthusiastic and speak clearly with good use of gestures and eye contact. Try not to read your presentation from prepared notes. Do not forget to engage with your audience. You will need to demonstrate that you have the ability to generate interest and also to interpret and answer questions in a way that provides useful additional insights into your work.

Structure Or Format of The Mechanical Engineering Thesis Final Report

A typical example of the general format of your engineering thesis report is shown below:

• Title page or Cover Page

Most universities provide a title page template for engineering thesis. You should closely follow the template without changing the format or layout. Typical contents of a title page include:

• Unit Code and Title
• Project Title
• Student Name and Student Number
• Name of your Degree and Specialisation
• Name of the University and the School
• Date of Submission
• Supervisor Name at the bottom of the page
• Disclaimer or Author Declaration

The wordings are usually provided in the project handbook.

It should provide a clear and concise summary of the project for a busy reader. Abstract should be self‐contained. It should enable a reader to quickly assess the subject matter of the report, to learn the essentials of the work carried out and the principal conclusions. It is used to give a clear picture of the aims and methods, and to summarise briefly the principal conclusions. It is intended to provide a frame of reference that will allow the nature of the project to be appreciated quickly. It is quite difficult to illustrate in a few words what your project set out to do. You may need several attempts before you achieve a sufficiently brief, informative Abstract. It is recommended that you write this section last, to ensure that it accurately reflects what is in the main body of the Engineering Thesis Final Report. You should not include figures, tables, or references in Abstract.

• Table of Contents

This section helps the reader to follow your structure and easily navigate to different section of your report. Check this YouTube video on How to Create Table of Contents in your report.

• List of Figures and Tables

All figures, graphs and tables in your engineering thesis report must be numbered, given a title/caption, identified sequentially and referred to in the text. Check this YouTube video on How to Create List of Figures or How to Create List of Tables in your report.

• List of appendices

List the appendices here if available in the report.

• Acknowledgements

This is an acknowledgement by the author of help given or work carried out by any other person or organisation

Chapter 1: Introduction

The introduction of a mechanical engineering dissertation should provide the reader with a clear idea of the issue under investigation and its importance, and such information as when and where it was carried out if that is not already obvious. This section should be as brief as possible, but should provide the reader with the necessary background information to give the setting of the investigation. Bear in mind your readers and how familiar they may or may not be with the situation. The introduction sets out the background to the project, states the problem investigated, notes the central focus of the investigation and mentions the proposed contribution to practical or theoretical issues. Therefore, the main subsections of the introduction chapter are:

This provides the reason for undertaking this engineering final year project and explains why the project is important. In this subsection, it is important to give sufficient background information and describe the current state of the art.

Under this subsection, define the objectives of the engineering dissertation. Identify the scope and the assumption. State the requirements (e.g., customer requirements, product requirements, system requirements, algorithm requirements, etc.)

• Significance

The significance subsection of the engineering thesis introduction chapter gives the expected benefits of this project. Explain how the objectives will advance the current state of the art.

Chapter 2: Background/ Literature Review

Literature review is an important chapter in engineering dissertation as it explains the context and background of the study. Theoretical or research oriented mechanical engineering thesis require a more detailed review of previous work compared to practical mechanical engineering thesis. In your literature review, it is important to set the scene and place the work in context so as to prepare the reader for what is to follow. If the project is one which has been done by other students in previous years it would usually be expected that this work will be critically reviewed to help define the starting point for the new project. Literature review also enables you to identify the gaps on the topic. Literature review findings also provide a means for verification and validation of your project results. Please note that the material to be reviewed must be selected such that only books and journal articles which relate directly to the topic are included. Remember to provide a summary of the literature review in a paragraph or two, clearly mentioning the main findings from the review.

Chapter 3:  Methodology

Depending on the type of your mechanical engineering thesis, this section may involve design of a product, model, test program, computer simulation, manufacture and development of a product etc. When writing the methodology chapter for your mechanical engineering dissertation, divide the project into a set of specific tasks and identify the appropriate and innovative approach to carry out each of these tasks. These tasks will vary depending on the type of engineering thesis . For theoretical or research orientated mechanical engineering final year projects, the methodology should identify the databases and bodies of literature that will drive the review and the approach that will be developed. For modelling and design-based engineering final year projects, identify the computing resources that will be used, or the platform for the development of any new software as well as the tools that will be required. For the experimental engineering dissertations, describe the equipment and specific techniques that have been employed. When proposing your methodology, you must first ascertain the availability and accessibility of experimental equipment, computing resources, work space, and so on

Chapter 4: Results

This is the heart of the Mechanical Engineering Thesis Final Report and will consist of text, graphs, tables and figures, depending on the type of the project. Raw data generated or obtained during project implementation should be given in this section and if voluminous should be placed in an appendix. Derived results appearing in the main text should then refer to the raw data. The way results are presented is important. Tables, charts, graphs and other figures should illustrate and illuminate the text. The text derived from the results should not duplicate information in the tables and figures. It should highlight the significant aspects of the findings, so that all relevant facts are presented in a way that draws the reader’s attention to what is most important.

Chapter 5: Discussion of Results

This section begins by first restating the problem that your mechanical engineering thesis addresses before discussing how the results affect existing knowledge of the subject. The following are some of the guidelines when writing your discussion:

• Try to present the principles, relationships and generalisation shown by the results.
• Point out any exceptions or lack of correlation; define unsettled points.
• Show how your results and interpretations agree or contrast with findings from the review of previous work.
• Discuss the engineering issues of the work, as well as any practical applications.

Chapter 6: Conclusions

Before writing the conclusions chapter of your engineering dissertation, read through the whole report and take note of the main points.  Only conclusions that can be justifiably drawn from the results should be made, and avoid including an opinion for which no evidence is provided in the report. Readers who want a quick idea of what the project is about will look at the abstract, possibly the introduction and almost certainly at the conclusions. Therefore, this section should be clearly expressed to enable readers to readily understand what work has been done and the conclusions that have been drawn from the results. Should state clearly what you have achieved and, in particular, whether you have fulfilled the aims and objectives of the project. If not, you should summarise why not.

Chapter 7:  Suggestions for Further Work or Recommendations

This section includes the main aspects of the project that require further development. Each aspect has to be covered in sufficient depth and be supported by argument. Many projects are continued by other students the following year, so this section should provide them with good guidance on what the next steps should be. This is an important section as the examiners often use this information to see how much you have learnt during the project.

Adequate and relevant references (scholarly and of good quality) should be provided with complete details and in a consistent and correct format. Ensure all references are cited properly in text. All references must have a corresponding in‐text citation. All facts that are not either common knowledge to engineers, or statements of your actions, findings or assumptions must be referenced. Use the referencing style recommended in your project handbook. Please consult your supervisor when in doubt.

Appendices should include items which are required for reference purposes, but which would clutter the main body of the engineering thesis final report. Appendices should contain material that may disturb the smooth reading of the report. Other documents like catalogues and technical data sheets should not be included unless they are likely to be unavailable to the reader (e.g., from online sources etc.)  – provide a reference(s) instead.

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Topengineeringsolutions.com has been providing engineering assignment help service to thousands of students for over a decade now. This includes engineering thesis help, mechanical engineering assignment help and other engineering assignment help services. Our tutors are also well versed with most engineering software packages including SolidWorks , ANSYS, MATLAB , Siemens NX, CATIA, SOLIDCAM, ABAQUS and many more. Thus, our mechanical engineering tutors are able to handle mechanical engineering final year projects that involve Computational Fluid Dynamics (CFD), Finite Element Analysis (FEA), Fluid Structure Interaction (FSI), 3D modelling, Acoustic analysis, Thermal Analysis, Combustion analysis and many more. We are also willing to help you select the most suitable mechanical engineering thesis topic to guarantee success. We incorporate the services of qualified, experienced, and professional staff to ensure students receive the best work that suits their needs. Our services are available 24/7 to ensure that we cater for both emergency and last-minute thesis projects. Our customer support staff is trained to engage students in a friendly yet professional manner to guarantee them high levels of satisfaction. Our qualified staffs pride themselves in numerous years of experience and knowledge gained from engaging students from all walks of life, and helping mechanical engineering final year student achieve his goals. Our services are reasonably priced to ensure that students from all backgrounds are able to access them.

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•   Mechanical Engineering Thesis
•   Electrical Engineering Thesis
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MS in Mechanical Engineering - Thesis Guidelines

Students may choose to pursue a thesis as part of their MS degree program, but only with the consent of a faculty advisor willing to supervise the thesis work. 

Preparation of a thesis representing an independent research work is a pivotal phase of this MS degree program. It provides the student with an opportunity to work on an open-ended problem, developing a particular solution that is not pre-determined and involving synthesis of knowledge and intellectual creativity. The thesis may involve an investigation that is fundamental in nature, or may be applied, incorporating theory, experimental testing and/or analytical modeling, and/or creative design. Through the thesis, candidates are expected to give evidence of competence in research and a sound understanding of the area of specialization involved. Students are also strongly encouraged to present their research at scientific conferences and publish the results of their thesis research in a peer-reviewed journal.

Students receive a grade of Y (incomplete) in these courses as long as the thesis in progress. Eventual thesis grades replace the incomplete grades upon formal completion of the thesis. In order to receive a grade of Y for ME-0296, students must submit a  thesis prospectus  that outlines the area of work, thesis goals, proposed approach and a review of relevant past work in the literature before the end of the first semester in which the student enrolls in ME-0296, typically the third semester of full-time study. An example of a recent MS thesis prospectus can be found in the Mechanical Engineering office.

The examining committee for MS candidates completing theses should be composed of three (3) members.

• Thesis advisor (committee chair)
• One technical expert outside of the ME department
• A third member of the committee, often another faculty member in the ME department

The committee chair is normally a full-time, tenure-track faculty member. One committee member must be from outside the ME department. Thesis normally counts as 9 credits towards the MS degree requirements. However, a student, with the approval of his/her thesis advisor, has the option to complete a 6-credit thesis by submitting a petition form to the Department. This petition must be signed by the student and the thesis advisor and will become part of the student's academic record. With a 6-credit thesis, a student must complete an extra graduate-level course (for a total of 8 courses) to fulfill the 30-credit requirement for graduation. This option is not typically available to those intending to pursue a Ph.D. degree. 

Thesis Completion

The MS thesis is completed upon:

• A successful oral defense (open to the community)
• Submittal of an approved thesis to the Office of Graduate Studies

The student should consult the  Graduate Student Handbook  for specific dates and deadlines for this process in the graduation semester.

UKnowledge > College of Engineering > Mechanical Engineering > Theses & Dissertations

Theses and Dissertations--Mechanical Engineering

Theses/dissertations from 2024 2024.

The Determination of Darcy Permeabilities and Slip Parameters in Porous Thermal Protection Media via Pressure-Driven Steady Flows at Varying Levels of Thermal Decomposition , John Ryan O'Nan

Theses/Dissertations from 2023 2023

Utilization of Uncrewed Aircraft Systems Towards Investigating the Structure of the Atmospheric Surface Layer , Loiy Al-Ghussain

MECHANICAL ENERGY HARVESTER FOR POWERING RFID SYSTEMS COMPONENTS: MODELING, ANALYSIS, OPTIMIZATION AND DESIGN , Alireza Babaei

Impact of spallation and internal radiation on fibrous ablative materials , Raghava Sai Chaitanya Davuluri

ANISOTROPIC MATERIAL BEHAVIOR OF 3D PRINTED FIBER COMPOSITES , Jordan Garcia

Stratospheric Glider Measurements of Atmospheric Parameters , Anisa Haghighi

Attrition Study of Copper-Supplemented Iron-Based Oxygen Carrier for Chemical Looping Combustion , Neng Huang

MACHINE LEARNING FOR ADVANCING AUTOMATION AND QUALITY CONTROL IN ROBOTIC WELDING , Joseph Kershaw

A computational fluid dynamic analysis of oxyacetylene combustion flow for use in material response boundary conditions , Craig Meade

MULTISCALE MODELING OF CARDIAC GROWTH AND BAROREFLEX CONTROL , Hossein Sharifi

Precision Meteorological Prediction Employing A Data-Driven, Adaptive, Real-Time (DART) Approach , Sujit Sinha

Parallel Real Time RRT*: An RRT* Based Path Planning Process , David Yackzan

Theses/Dissertations from 2022 2022

IN-SITU CHARACTERIZATION OF SURFACE QUALITY IN γ-TiAl AEROSPACE ALLOY MACHINING , David Adeniji

NUMERICAL AND SCALING STUDY ON APPLICATION OF INKJET TECHNOLOGY TO AUTOMOTIVE COATING , Masoud Arabghahestani Dr.

EXPERIMENTAL INVESTIGATION OF ROUGHNESS AND BLOWING EFFECTS OVER ABLATOR-LIKE SURFACES , Colby Borchetta

Energy and Economic Modeling of Stillage Dewatering Processes in Kentucky Bourbon Distilleries , William Brennan

Peridynamic Material Correspondence Models: Bond-Associated and Higher-Order Formulations , WaiLam Chan

A Decoupled Engineering Methodology for Accurate Prediction of Ablative Surface Boundary Conditions in Thermal Protection Systems , Justin Cooper

QUANTITATIVE METHODS FOR TOTAL LIFECYCLE RISK LIKELIHOOD AND IMPACT ASSESSMENT IN SUSTAINABLE PRODUCT DESIGN DECISION MAKING , Christian Enyoghasi

Numerical Investigation of an Oxyacetylene Torch With Regards to an Ablative Material , Luke Fortner

Formation Control with Collision Avoidance for Fixed-Wing Unmanned Air Vehicles With Speed Constraints , Christopher Heintz

Radiative Conductivity Estimation Using Direct Approach For Fibrous Materials , Mohammad Khaleel

Modeling Human Control Behavior in Command-following Tasks , Sajad Koushkbaghi

Formation Control with Bounded Controls and Collision Avoidance: Theory and Application to Quadrotor Unmanned Air Vehicles , Zachary S. Lippay

Small-Satellite Attitude Control Using Sinusoidal Actuator Motion: Experiments on the International Space Station , K. Ryan Lush

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• Senior Thesis

For an A.B. degree, a research thesis is strongly encouraged but not required; a thesis is necessary to be considered for High or Highest Honors. Additionally, a thesis will be particularly useful for students interested in pursuing graduate engineering research. 

In the S.B. degree programs, every student completes a design thesis as part of the required senior capstone design course (ES 100hf). During the year-long course students design and prototype a solution to an engineering problem of their own choice.

The guide below provides an overview of the requirement for an A.B. thesis in Mechanical Engineering:

• Engineering A.B. Thesis Guide

Some recent thesis examples across all of SEAS can be found on the Harvard DASH (Digital Access to Scholarship at Harvard) repository .

Mechanical Engineering Senior thesis examples:

• Prototyped a mug to keep tea the perfect drinking temperature using a novel wax substrate for thermal control

Engineering A.B. Thesis Extensions and Late Submissions

Thesis extensions will only be granted in extraordinary circumstances, such as hospitalization or grave family emergency. An extension may only be granted by the DUS (who may consult with thesis advisor, resident dean, and readers). For joint concentrators, the other concentration should also support the extension. To request an extension, please email your ADUS or DUS, ideally several business days in advance. Please note that any extension must be able to fall within our normal grading, feedback, and degree recommendation deadline, so extensions of more than a few days are usually impossible.

Late submissions of thesis work will not be accepted. A thesis is required for joint concentrators, and a late submission will prevent a student from fulfilling this requirement. Please plan ahead and submit your thesis by the required deadline.

Senior Thesis Submission Information for A.B. Programs

Senior A.B. theses are submitted to SEAS and made accessible via the Harvard University Archives and optionally via  DASH  (Digital Access to Scholarship at Harvard), Harvard's open-access repository for scholarly work.

In addition to submitting to the department and thesis advisors & readers, each SEAS senior thesis writer will use an online submission system to submit an electronic copy of their senior thesis to SEAS; this electronic copy will be kept at SEAS as a non-circulating backup. Please note that the thesis won't be published until close to or after the degree date. During this submission process, the student will also have the option to make the electronic copy publicly available via DASH.  Basic document information (e.g., author name, thesis title, degree date, abstract) will also be collected via the submission system; this document information will be available in  HOLLIS , the Harvard Library catalog, and DASH (though the thesis itself will be available in DASH only if the student opts to allow this). Students can also make code or data for senior thesis work available. They can do this by posting the data to the Harvard  Dataverse  or including the code as a supplementary file in the DASH repository when submitting their thesis in the SEAS online submission system.

Whether or not a student opts to make the thesis available through DASH, SEAS will provide an electronic record copy of the thesis to the Harvard University Archives. The Archives may make this record copy of the thesis accessible to researchers in the Archives reading room via a secure workstation or by providing a paper copy for use only in the reading room.  Per University policy , for a period of five years after the acceptance of a thesis, the Archives will require an author’s written permission before permitting researchers to create or request a copy of any thesis in whole or in part. Students who wish to place additional restrictions on the record copy in the Archives must contact the Archives  directly, independent of the online submission system. 

Students interested in commercializing ideas in their theses may wish to consult Dr. Fawwaz Habbal , Senior Lecturer on Applied Physics, about patent protection. See Harvard's policy for information about ownership of software written as part of academic work.

In Materials Science & Mechanical Engineering

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List Of Project/Thesis Topics For M.E. /M.TECH Mechanical Engineers.

• STRUCTURAL ANALYSIS OF A FLAT
• BED VIBRATION ANALYSIS OF A FLATBED 
• MECHANICAL AND THERMAL BUCKLING OF THIN FILMS 
• FATIGUE RESISTANCE ANALYSIS OF A FUEL INJECTION COMPONENT 
• DESIGN /ANALYSIS OF MACHINE TOOL ELEMENTS USING UNIGRAPHICS/ANSYS 
• VIBRATION ANALYSIS OF A ROTARY COMPRESSOR 
• FIELD PROBLEM OF A CABIN MOUNTING BRACKET OF LOAD-KING PRIDE 
• DESIGN AND ANALYSIS OF MINIATURE POSITIVE DISPLACEMENT PUMP 
• CAVITATION IN THE COOLING FLUID OF AN IC DIESEL ENGINE DUE TO FORCES GENERATED IN A PISTON-CYLINDER ASSEMBLY 
• INVESTIGATIONS ON SLIDING CONTACT CHARACTERISTICS OF FRP COMPOSITE BEARINGS 

• CUTTING DYNAMICS OF HIGH SPEED MACHINING OF THIN RIBBED STRUCTURES 
• STABILITY ANALYSIS OF BALL BEARING CONSIDERING THE EFFECT OF WAVINESS IN BALL BEARING ASSEMBLY SYNOPSIS 
• PRE-STRESSED MODAL ANALYSIS OF ENGINE SHROUD OF LAWN BOY ENGINE 
• OPTIMIZATION OF DIE EXTRUSION PARAMETERS USING FEM. 
• RANDOM VIBRATION ANALYSIS OF COMPRESSOR HOUSING: 
• OPTIMUM DESIGN AND ANALYSIS OF COMPOSITE DRIVE SHAFT FOR AN AUTOMOBILE 
• STRUCTURAL ANALYSIS OF A REFRIGERATOR COMPRESSOR CRANK SHAFT 
• STRUCTURAL STATIC ANALYSIS ON CRANKSHAFT BEARING ASSEMBLY 
• MODAL ANALYSIS OF INTAKE MANIFOLD OF A CARBURETTOR 
• STRUCTURAL STATIC ANALYSIS OF CYLINDER HEAD 
• OPTIMIZATION OF THE JIG DESIGN 
• MODAL ANALYSIS OF REFRIGERATOR COMPRESSOR CYLINDER HEAD 
• MODAL ANALYSIS OF VALVE PLATES AND COMPARE THE RESULTS BETWEEN THE TWO VALVE PLATES. 
• MODAL ANALYSIS OF SUCTION VALVE 
• TO PERFORM STRUCTURAL STATIC ANALYSIS ON A CRANK SHAFT 
• TO PERFORM STRUCTURAL STATIC ANALYSIS ON A FLANGE: 
• SIMULATION OF CENTRIFUGAL PUMP PERFORCE USING CFD TOOL AND OPTIMIZATION OF THE PUMP FOR THE IMPROVED PERFORMANCE 
• MODAL ANALYSIS OF MUFFLER GUARD 
• Thermal analysis of Coolant Plumbing pipe 
• HEAT TRANSFER IN THE CYLINDER HEAD OF A TWO-STROKE ENGINE 
• Chasis design for HCV 
• Analysis Of A C Class Adhesively Bonded Car Floor Structure Joints
• Analysis Of A C Class Spot Welded Car Floor Structure Joints
• Automotive System Design Of Lcv (Low Carbon Vehicle) Pick Up
• Briquette Manufacturing In A Controlled Environment And Its Effects On Combustion
•  Crash Analysis Of Student Model Lcv Chassis For Low And High Speed Rear Impact
• Design And Analysis Of Battery Carrying Structure Of An Automobile For Static And Dynamic Loading
• Design Of Lcv (Low Carbon Vehicle) Diesel Hybrid Suv
• Front Crash Analysis Of Student Model Lcv Chassis
• Projects For Mechanical Engineering Students
• Regenerative Suspension System Retrofitted To The Vehicle
• Retrofit Kers (Kinetic Energy Recovery System) To Land Rover Vehicle
• Study And Research On Regenerative Braking System
• Study On Structural Behavior Of Automotive Muffler Through Fea
• Study On Thermal Behavior Of Automotive Muffler
• Study On Thermal Behavior Of Manifold Assembly
• Thermal Behavior Of Exhaust Manifold (Thermal Fatigue Analysis)
• Thermo Electric Energy Recovery System

CAD / CAM Projects List - Abstract , Report Download

New Mechanical Projects 2020 ( All Projects Post Index List )

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Sachin Thorat

Sachin is a B-TECH graduate in Mechanical Engineering from a reputed Engineering college. Currently, he is working in the sheet metal industry as a designer. Additionally, he has interested in Product Design, Animation, and Project design. He also likes to write articles related to the mechanical engineering field and tries to motivate other mechanical engineering students by his innovative project ideas, design, models and videos.

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Thesis - Mechanical Engineering BSc | Faculty of Engineering

Thesis - mechanical engineering bsc.

2023/2024/2

Submission deadline for Thesis : 15 May 2024 12 PM (noon)

bound copy submitted in person and electronic version uploaded to the e-learning platform

Deadline for obligatory plagiarism check :  8 May 2024 See details here . class ID: 38925991 class enrollment key: 20240325

Please only upload the version approved by your supervisor.

Please note that extensions to the above deadline are not allowed.

Thesis is the creative elaboration of a professional task (scientific, engineering, design, development, research or research development) in written form as defined in the requirements of the training program. By solving the task the student relies on his/her studies using national and international literature under the guidance of an internal and external supervisor. By preparing and defending thesis students who complete the Mechanical Engineering undergraduate program prove that they are capable of the practical applications of the acquired skills, summarizing the work done and its results in a professional way, creatively solving the tasks related to the topic and doing individual professional work.

Step-by-step guide to writing thesis

• Registering for the course MFZDG31G15-EN/MFZDG31G413-EN or MK3SZDGG15G117-EN/MK3SZDGG15G317-EN "Thesis"

If you know which topic you would like to choose or which field of mechanical engineering you are interested in, you should contact an instructor from the Faculty whom you would like as your supervisor. Possible thesis topics here . If he/she accepts your topic, you can register for his/her "Thesis" course at the beginning of the semester via the NEPTUN system. You can sign up for the course usually through the Department or the International Office (Faculty of Engineering).

• Thesis Sheet

The Thesis Sheet is prepared by the Department and must be bound into the thesis. You are kindly requested to print out this final version and have it bound into thesis. The Department will arrange for the signature of the Head of Department.

The Thesis Sheet includes the following data:

• name of the student, name of the specialization, full-time training
• title of the thesis, 
• tasks to be elaborated (generally the same as the chapters of the thesis) in imperative form (Please present...!, Please make...!),
• name of the internal tutor (supervisor), 
• name of the external tutor, name of the company,
• two selected subjects of the state exam (see: Important information on state exam).
• Regular consultation with the supervisor (certified on the Consultation Sheet)

During the semester you will have two guiders, one instructor from the Faculty and one external supervisor. The external supervisor (referee) is usually an expert from a company where you can do for example additional research work or measurements according to your topic.

During the semester students have to give account of the current state of the thesis to the internal tutor at least three times , which is certified on the Consultation Sheet. The Consultation Sheet is made out and managed by the supervisor . Thesis can be submitted at the end of the semester after the supervisor's approval on the Consultation Sheet. The grade earned for the "Thesis" course is not identical with the grade received for the final evaluation of thesis. However, submitting thesis (as outlined below) is one of the requirements of taking the state exam.

• Submitting thesis

Formal Thesis Requirements (minimum number of pages, font style and size, requirements regarding the content, etc.) may be downloaded here .

Content of thesis and possible thesis topics are available here .

Template for thesis here .

Guide to referencing here .

Plagiarism is strictly forbidden! Students have to sign the Plagiarism Declaration which must be bound into thesis. The Plagiarism Declaration must be filled out electronically, as well.

To be handed in:  

• 1 bound copy (After the state exam this bound copy is given back to the student. The department stores theses exclusively in electronic version. Please note the external supervisor may request an additional bound copy of the thesis.)

The following must be bound into the thesis (in this sequence):

• Thesis Sheet (with serial number and signature of the head of department) – can be requested from the secretariat (it is not the sheet signed by the company!, see above),
• Supervisor's Declaration     (signed by the internal supervisor). The internal supervisor keeps a record of the Consultation Sheet. The grade for the course, called Thesis on Neptun will be decided upon on the basis of the Consultation Sheet. The internal supervisor retains it and it is not to be bound into thesis. On the Supervisor's Declaration Sheet the internal supervisor states that the thesis meets the requirements concerning content and format and it is suitable for submission. One of the preconditions for signing the Supervisor's Declaration is to complete the "Thesis" course. The Supervisor's Declaration must be bound into thesis.
• Plagiarism  Declaration – must be filled out electronically and signed by the student,
• ( Confidentiality Agreement , only if the company requests it, as the topic is confidential.)

Confidentiality Agreement in Hungarian is available below:

Template for Confidentiality Agreement (University - Company)

Template for Confidentiality Agreement (Student - Company)

To be handed in with the thesis, but not bound :

• Max. 1 page abstract in English containing the name of the student, the title of the thesis, and the brief summary of the topic, with readable signature, 
• Max. 1 page abstract in Hungarian containing the name of the student, the title of the thesis, and the brief summary of the topic, with readable signature. The abstracts are not identical with the “Summary” chapter of the thesis, though obviously similar to its content. It contains the title of the thesis, (if applicable: the company which gave the background for preparing thesis), the objectives, topics and tasks elaborated by the student, the methods applied, the conclusion or evaluation in some sentences, applicability of the results. Both abstracts are previously proofread by the responsible of the major, Dr Zsolt Tiba. Before final submission please send both abstracts electronically to your internal supervisor. Layout of the abstracts: max. 1-page long (DIN A4); between 2400 and 2500 characters (including spaces, without name, title, date, signature).
• Consultation Sheet

Electronic versions

To be uploaded: The thesis must also be uploaded to the e-learning platform (individual upload) and DEA (organized, collective live upload, date: submission deadline).

5. Thesis Review Report

The Thesis Review Report is prepared by the Department and written by the external supervisor.

6. Improving thesis with a fail mark

If thesis is evaluated with a fail mark by the referee, the head of department may decide to allocate a new referee to review thesis. If thesis is evaluated with a fail mark by the head of department, the student is not allowed to take the final exam and is supposed to prepare a new thesis. Conditions on resubmitting thesis are defined by the program coordinator, in case of Building Services Engineering Specialization the head of department who is in charge of the specialization.

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Top 50 Emerging Research Topics in Mechanical Engineering

Explore the forefront of innovation in mechanical engineering

Mechanical engineering is a constantly evolving field that shapes our world, from the micro-scale of nanotechnology to the macro-scale of heavy machinery. With technological advancements and societal demands driving innovation, numerous emerging research topics are gaining traction in the domain of mechanical engineering. These areas encompass a wide array of disciplines, promising groundbreaking developments and solutions to complex challenges. Here, iLovePhD presents you a list of the top 50 emerging research topics in the field of Mechanical Engineering.

Explore the forefront of innovation in mechanical engineering with our curated list of the Top 50 Emerging Research Topics. From 3D printing to AI-driven robotics, delve into the latest trends shaping the future of this dynamic field

1. Additive Manufacturing and 3D Printing

Multi-Material 3D Printing: Explore techniques for printing with multiple materials in a single process to create complex, multi-functional parts.

In-Situ Monitoring and Control: Develop methods for real-time monitoring and control of the printing process to ensure quality and accuracy.

Bio-printing : Investigate the potential of 3D printing in the field of tissue engineering and regenerative medicine.

Sustainable Materials for Printing : Research new eco-friendly materials and recycling methods for additive manufacturing.

2. Advanced Materials and Nanotechnology

Nanostructured Materials: Study the properties and applications of materials at the nanoscale level for enhanced mechanical, thermal, and electrical properties.

Self-Healing Materials: Explore materials that can repair damage autonomously, extending the lifespan of components.

Graphene-based Technologies: Investigate the potential of graphene in mechanical engineering, including its use in composites, sensors, and energy storage.

Smart Materials: Research materials that can adapt their properties in response to environmental stimuli, such as shape memory alloys.

3. Robotics and Automation

Soft Robotics: Explore the development of robots using soft and flexible materials, enabling safer human-robot interactions and versatile applications.

Collaborative Robots (Cobots ): Investigate the integration of robots that can work alongside humans in various industries, enhancing productivity and safety.

Autonomous Systems: Research algorithms and systems for autonomous navigation and decision-making in robotic applications.

Robot Learning and Adaptability: Explore machine learning and AI techniques to enable robots to learn and adapt to dynamic environments.

4. Energy Systems and Sustainability

Renewable Energy Integration: Study the integration of renewable energy sources into mechanical systems, focusing on efficiency and reliability.

Energy Storage Solutions: Investigate advanced energy storage technologies, such as batteries, supercapacitors, and fuel cells for various applications.

Waste Heat Recovery: Research methods to efficiently capture and utilize waste heat from industrial processes for energy generation.

Sustainable Design and Manufacturing: Explore methodologies for sustainable product design and manufacturing processes to minimize environmental impact.

5. Biomechanics and Bioengineering

Prosthetics and Orthotics: Develop advanced prosthetic devices that mimic natural movement and enhance the quality of life for users.

Biomimicry: Study natural systems to inspire engineering solutions for various applications, such as materials, structures, and robotics.

Tissue Engineering and Regenerative Medicine: Explore methods for creating functional tissues and organs using engineering principles.

Biomechanics of Human Movement: Research the mechanics and dynamics of human movement to optimize sports performance or prevent injuries.

6. Computational Mechanics and Simulation

Multi-scale Modelling: Develop models that span multiple length and time scales to simulate complex mechanical behaviors accurately.

High-Performance Computing in Mechanics: Explore the use of supercomputing and parallel processing for large-scale simulations.

Virtual Prototyping: Develop and validate virtual prototypes to reduce physical testing in product development.

Machine Learning in Simulation: Explore the use of machine learning algorithms to optimize simulations and model complex behaviors.

7. Aerospace Engineering and Aerodynamics

Advanced Aircraft Design: Investigate novel designs that enhance fuel efficiency, reduce emissions, and improve performance.

Hypersonic Flight and Space Travel: Research technologies for hypersonic and space travel, focusing on propulsion and thermal management.

Aerodynamics and Flow Control: Study methods to control airflow for improved efficiency and reduced drag in various applications.

Unmanned Aerial Vehicles (UAVs): Explore applications and technologies for unmanned aerial vehicles, including surveillance, delivery, and agriculture.

8. Autonomous Vehicles and Transportation

Vehicular Automation: Develop systems for autonomous vehicles, focusing on safety, decision-making, and infrastructure integration.

Electric and Hybrid Vehicles: Investigate advanced technologies for electric and hybrid vehicles, including energy management and charging infrastructure.

Smart Traffic Management: Research systems and algorithms for optimizing traffic flow and reducing congestion in urban areas.

Vehicle-to-Everything (V2X) Communication: Explore communication systems for vehicles to interact with each other and with the surrounding infrastructure for enhanced safety and efficiency.

9. Structural Health Monitoring and Maintenance

Sensor Technologies: Develop advanced sensors for real-time monitoring of structural health in buildings, bridges, and infrastructure.

Predictive Maintenance: Implement predictive algorithms to anticipate and prevent failures in mechanical systems before they occur.

Wireless Monitoring Systems: Research wireless and remote monitoring systems for structural health, enabling continuous surveillance.

Robotic Inspection and Repair: Investigate robotic systems for inspection and maintenance of hard-to-reach or hazardous structures.

10. Manufacturing Processes and Industry 4.0

Digital Twin Technology: Develop and implement digital twins for real-time monitoring and optimization of manufacturing processes.

Internet of Things (IoT) in Manufacturing: Explore IoT applications in manufacturing for process optimization and quality control.

Smart Factories: Research the development of interconnected, intelligent factories that optimize production and resource usage.

Cybersecurity in Manufacturing: Investigate robust Cybersecurity measures for safeguarding interconnected manufacturing systems from potential threats.

Top 50 Emerging Research Ideas in Mechanical Engineering

• Additive Manufacturing and 3D Printing: Exploring novel materials, processes, and applications for 3D printing in manufacturing, aerospace, healthcare, etc.
• Advanced Composite Materials: Developing lightweight, durable, and high-strength composite materials for various engineering applications.
• Biomechanics and Bioengineering: Research focusing on understanding human movement, tissue engineering, and biomedical devices.
• Renewable Energy Systems: Innovations in wind, solar, and hydrokinetic energy, including optimization of energy generation and storage.
• Smart Materials and Structures: Research on materials that can adapt their properties in response to environmental stimuli.
• Robotics and Automation: Enhancing automation in manufacturing, including collaborative robots, AI-driven systems, and human-robot interaction.
• Energy Harvesting and Conversion: Extracting energy from various sources and converting it efficiently for practical use.
• Micro- and Nano-mechanics: Studying mechanical behavior at the micro and nanoscale for miniaturized devices and systems.
• Cyber-Physical Systems: Integration of computational algorithms and physical processes to create intelligent systems.
• Industry 4.0 and Internet of Things (IoT): Utilizing IoT and data analytics in manufacturing for predictive maintenance, quality control, and process optimization.
• Thermal Management Systems: Developing efficient cooling and heating technologies for electronic devices and power systems.
• Sustainable Manufacturing and Design: Focus on reducing environmental impact and improving efficiency in manufacturing processes.
• Artificial Intelligence in Mechanical Systems: Applying AI for design optimization, predictive maintenance, and decision-making in mechanical systems.
• Adaptive Control Systems: Systems that can autonomously adapt to changing conditions for improved performance.
• Friction Stir Welding and Processing: Advancements in solid-state joining processes for various materials.
• Hybrid and Electric Vehicles: Research on improving efficiency, battery technology, and infrastructure for electric vehicles.
• Aeroelasticity and Flight Dynamics: Understanding the interaction between aerodynamics and structural dynamics for aerospace applications.
• MEMS/NEMS (Micro/Nano-Electro-Mechanical Systems): Developing tiny mechanical devices and sensors for various applications.
• Soft Robotics and Bio-inspired Machines: Creating robots and machines with more flexible and adaptive structures.
• Wearable Technology and Smart Fabrics: Integration of mechanical systems in wearable devices and textiles for various purposes.
• Human-Machine Interface: Designing intuitive interfaces for better interaction between humans and machines.
• Precision Engineering and Metrology: Advancements in accurate measurement and manufacturing techniques.
• Multifunctional Materials: Materials designed to serve multiple purposes or functions in various applications.
• Ergonomics and Human Factors in Design: Creating products and systems considering human comfort, safety, and usability.
• Cybersecurity in Mechanical Systems: Protecting interconnected mechanical systems from cyber threats.
• Supply Chain Optimization in Manufacturing: Applying engineering principles to streamline and improve supply chain logistics.
• Drones and Unmanned Aerial Vehicles (UAVs): Research on their design, propulsion, autonomy, and applications in various industries.
• Resilient and Sustainable Infrastructure: Developing infrastructure that can withstand natural disasters and environmental changes.
• Space Exploration Technologies: Advancements in propulsion, materials, and systems for space missions.
• Hydrogen Economy and Fuel Cells: Research into hydrogen-based energy systems and fuel cell technology.
• Tribology and Surface Engineering: Study of friction, wear, and lubrication for various mechanical systems.
• Digital Twin Technology: Creating virtual models of physical systems for analysis and optimization.
• Electric Propulsion Systems for Satellites: Improving efficiency and performance of electric propulsion for space applications.
• Humanitarian Engineering: Using engineering to address societal challenges in resource-constrained areas.
• Optimization and Design of Exoskeletons: Creating better wearable robotic devices to assist human movement.
• Nanotechnology in Mechanical Engineering: Utilizing nanomaterials and devices for mechanical applications.
• Microfluidics and Lab-on-a-Chip Devices: Developing small-scale fluid-handling devices for various purposes.
• Clean Water Technologies: Engineering solutions for clean water production, treatment, and distribution.
• Circular Economy and Sustainable Design: Designing products and systems for a circular economic model.
• Biologically Inspired Design: Drawing inspiration from nature to design more efficient and sustainable systems.
• Energy-Efficient HVAC Systems: Innovations in heating, ventilation, and air conditioning for energy savings.
• Advanced Heat Exchangers: Developing more efficient heat transfer systems for various applications.
• Acoustic Metamaterials and Noise Control: Designing materials and systems to control and manipulate sound.
• Smart Grid Technology: Integrating advanced technologies into power grids for efficiency and reliability.
• Renewable Energy Integration in Mechanical Systems: Optimizing the integration of renewable energy sources into various mechanical systems.
• Smart Cities and Infrastructure: Applying mechanical engineering principles to design and develop sustainable urban systems.
• Biomimetic Engineering: Mimicking biological systems to develop innovative engineering solutions.
• Machine Learning for Materials Discovery: Using machine learning to discover new materials with desired properties.
• Health Monitoring Systems for Structures: Developing systems for real-time monitoring of structural health and integrity.
• Virtual Reality (VR) and Augmented Reality (AR) in Mechanical Design: Utilizing VR and AR technologies for design, simulation, and maintenance of mechanical systems.

Mechanical engineering is a vast and dynamic field with ongoing technological advancements, and the above list represents a glimpse of the diverse research areas that drive innovation. Researchers and engineers in this field continue to push boundaries, solving complex problems and shaping the future of technology and society through their pioneering work. The evolution and interdisciplinary nature of mechanical engineering ensure that new and exciting research topics will continue to emerge, providing solutions to challenges and opportunities yet to be discovered.

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110 Engineering Research Topics For Engineering Students!

Getting engineering topics for research or presentation is not an easy task. The reason is that the field of engineering is vast. Engineers seek to use scientific principles in the design and building of machines, structures, bridges, tunnels, etc.

Engineering as a discipline has a broad range of specialized fields such as chemical engineering, civil engineering, biomedical engineering, computer engineering, mechanical engineering, software engineering, and lots more! In all, engineering seeks to apply mathematics or science to solving problems.

110 Engineering Topic Ideas in Different Areas

Genetic engineering topics, mechanical engineering research topics, electrical engineering research topics, software engineering research topics, computer engineering research topics, biomedical engineering research topics, civil engineering topics, chemical engineering research topics, controversial engineering topics, aerospace engineering topics, industrial engineering topics, environmental engineering topics for research.

We understand how difficult and tiring it could be to get engineering research topics; hence this article contains a total of 110 interesting engineering topics covering all aspects of engineering. Ready to explore? Let’s begin right away!

Genetic engineering is the direct manipulation of the gene of an organism using biotechnology. Many controversies are surrounding this engineering field because of the fantastic potential feats it could achieve. Here are some genetic engineering topics that encompass essential areas of this field.

• Can the human personality be altered through genetic engineering?
• Genetic engineering: hope for children with intellectual disabilities?
• Genetic engineering: the problems and perspectives.
• Genetic engineering and the possibility of human cloning.
• Genetic Engineering
• The side effects of altering human personality
• Immortalizing humans through genetic engineering
• Addressing human deficiencies through genetic engineering

Mechanical engineering deals with the design and manufacture of physical or automated systems. These systems include power and energy systems, engines, compressors, kinematic chains, robotics, etc. Here are some impressive mechanical engineering topics that double as mechanical engineering thesis topics too.

• A study of the compressed air technology used in cars.
• The design of a motorized automatic wheelchair that can serve as a bed.
• The why and how of designing stronger and lighter automobiles.
• The design of an electronic-assisted hydraulic braking system.
• Basics of Electronics Engineering
• AC and DC motors and operations
• Design and implementation of wind energy
• Power lines and electricity distribution
• Electromagnetic field and its applications
• Generators and electric motors

Electrical engineering is a trendy and well-sought field that deals with the design and manufacture of different electrical and electronic systems. Electrical engineering encompasses power and electronics. The basic principle of digital technology and electricity are all given birth to in this field. From your lighting to computers and phones, everything runs based on electricity. Although finding topics in electrical engineering could be difficult, we have carefully selected four electrical engineering topics to give you a great head start in your research! or write research paper for me

• A study on how temperature affects photovoltaic energy conversion.
• The impact of solar charging stations on the power system.
• Direct current power transmission and multiphase power transmission
• Analysis of the power quality of the micro grid-connected power grid.
• Solar power and inverters
• Alternator and electric magnetic induction
• AC to DC converters
• Operational amplifiers and their circuits.

Software engineering deals with the application of engineering approaches systematically to develop software. This discipline overlaps with computer science and management science and is also a part of overall systems engineering. Here are some software engineering topics for your research!

• The borderline between hardware and software in cloud computing.
• Essential computer languages of the future.
• Latest tendencies in augmented reality and virtual reality.
• How algorithms improve test automation.
• Essentials for designing a functional software
• Software designing and cyber security
• 5 computer languages that will stand the test of time.
• Getting software design right
• Effects of malware on software operation.

Computer engineering integrates essential knowledge from the subfields of computer science, software engineering, and electronic engineering to develop computer hardware and software. Computer engineering applies various concepts to build complex structural models. Besides, we have completed researches in the information technology field and prepare great  it thesis topics for you. Here are some computer engineering topics to help you with your research.

• Biotechnology, medicine, and computer engineering.
• Programs for computer-aided design (cad) of drug models.
• More effective coding and information protection for multinational companies.
• Why we will need greater ram in modern-day computers.
• Analysis and computer-aided structure design
• Pre-stressed concrete structures and variations
• General computer analysis of structures
• Machine foundation and structural design
• Storage and industrial structures.

Biomedical engineering applies principles and design concepts from engineering to medicine and biology for diagnostic or therapeutic healthcare purposes. Here are some suggested biomedical engineering topics to carry out research on!

• A study on how robots are changing health care.
• Can human organs be replaced with implantable biomedical devices?
• The advancement of brain implants.
• The advancement of cell and tissue engineering for organ replacement.
• Is planting human organs in machines safe?
• Is it possible to plant biomedical devices insensitive to human organs?
• How can biomedicine enhance the functioning of the human brain?
• The pros and cons of organ replacement.

Civil engineering deals with the construction, design, and implementation of these designs into the physical space. It is also responsible for the preservation and maintenance of these constructions. Civil engineering spans projects like roads, buildings, bridges, airports, and sewage construction. Here are some civil engineering topics for your research!

• Designing buildings and structures that withstand the impact of seismic waves.
• Active noise control for buildings in very noisy places.
• The intricacies of designing a blast-resistant building.
• A compatible study of the effect of replacing cement with silica fume and fly ash.
• Comparative study on fiber-reinforced concrete and other methods of concrete reinforcement.
• Advanced construction techniques
• Concrete repair and Structural Strengthening
• Advanced earthquake resistant techniques
• Hazardous waste management
• Carbon fiber use in construction
• Structural dynamics and seismic site characterization
• Urban construction and design techniques

Chemical engineering transverses the operation and study of chemical compounds and their production. It also deals with the economic methods involved in converting raw chemicals to usable finished compounds. Chemical engineering applies subjects from various fields such as physics, chemistry, biology, and mathematics. It utilizes technology to carry out large-scale chemical processes. Here are some chemical engineering topics for you!

• Capable wastewater treatment processes and technology.
• Enhanced oil recovery with the aid of microorganisms.
• Designing nanoparticle drug delivery systems for cancer chemotherapy.
• Efficient extraction of hydrogen from the biomass.
• Separation processes and thermodynamics
• Heat, mass, and temperature
• Industrial chemistry
• Water splitting for hydrogen production
• Mining and minerals
• Hydrocarbon processes and compounds
• Microfluidics and Nanofluidics.

Not everyone agrees on the same thing. Here are some engineering ethics topics and controversial engineering topics you can explore.

• Are organic foods better than genetically modified foods?
• Should genetically modified foods be used to solve hunger crises?
• Self-driving cars: pros and cons.
• Is mechanical reproduction ethical?
• If robots and computers take over tasks, what will humans do?
• Are electric cars really worth it?
• Should human genetics be altered?
• Will artificial intelligence replace humans in reality?

Aerospace engineering deals with the design, formation, and maintenance of aircraft, spacecraft, etc. It studies flight safety, fuel consumption, etc. Here are some aerospace engineering topics for you.

• How the design of planes can help them weather the storms more efficiently.
• Current techniques on flight plan optimization.
• Methods of optimizing commercial aircraft trajectory
• Application of artificial intelligence to capacity-demand.
• Desalination of water
• Designing safe planes
• Mapping a new airline route
• Understanding the structural design of planes.

Petroleum engineering encompasses everything hydrocarbon. It is the engineering field related to the activities, methods, processes, and adoptions taken to manufacture hydrocarbons. Hydrocarbon examples include natural gas and crude oil which can be processed to more refined forms to give new petrochemical products.

• The effect of 3d printing on manufacturing processes.
• How to make designs that fit resources and budget constraints.
• The simulation and practice of emergency evacuation.
• Workers ergonomics in industrial design.
• Heat transfer process and material science
• Drilling engineering and well formation
• Material and energy flow computing
• Well log analysis and testing
• Natural gas research and industrial management

Manufacturing engineering is integral for the creation of materials and various tools. It has to do with the design, implementation, construction, and development of all the processes involved in product and material manufacture. Some useful production engineering topics are:

• Harnessing freshwater as a source of energy
• The design and development of carbon index measurement systems.
• Process improvement techniques for the identification and removal of waste in industries.
• An extensive study of biomedical waste management.
• Optimization of transportation cost in raw material management
• Improvement of facility layout using systematic planning
• Facilities planning and design
• Functional analysis and material modeling
• Product design and marketing
• Principles of metal formation and design.

So here we are! 110 engineering research paper topics in all major fields of engineering! Choose the ones you like best and feel free to contact our thesis writers for help. It’s time to save humanity!

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[100+] Mechanical Engineering Research Topics For College Students With Free [Thesis Pdf] 2022

Are You Searching Research Topics For Mechanical Engineering ,   Topics For Mechanical Engineering Research Paper, Mechanical Engineering Research Topics For Students, Research Topics Ideas For Mechanical Engineering, Mechanical Engineering Research Topics For Phd, Mechanical Engineering Phd Topics. So You are at right place. At this website you can get lots of Mechanical Engineering Research Topics for College Students,  Phd, Mphil, Dissertations, Thesis, Project, Presentation, Seminar or Workshop.

In this article we provide you latest research topics for Mechanical Engineering with full Phd thesis. By these research topics for Mechanical Engineering you can get idea for your research work.  Check the suggestions below that can help you choose the right research topics for Mechanical Engineering : You can also Free Download Cyber Crime Research Phd Thesis in Pdf by given link.

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Research Topic For Mechanical Engineering 2023

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Mechanical Engineering Thesis Titles and Statements

1: DIGITAL TWIN FOR INTEGRATION OF DESIGN- MANUFACTURING – MAINTENANCE

Digital twin systems provide design-manufacturing-maintenance platforms that are unified and intelligent in that processes can be inferred and risks mitigated. Creating a digital twin follows a series of steps. First, a blueprint for its functionality is outlined. Second, the digital base twin is developed using AR tools such as IoT and 3D visualizations. Third, the digital environment is scaled to capture the physical environment. Finally, its capability is refined through navigation nodes built by machine learning and AI.

TOPIC 2: 3D PRINTING INFRASTRUCTURE FOR DATA  MANAGEMENT AND CLOUD-BASED ADDITIVE MANUFACTURING

3D printing processes are efficient in providing cheap, quick and versatile manufacturing. The 3D printing process starts with a CAD model designed using 3D software such as Maya, ZBrush and Houdini. An STL (3MF File) is generated and transformed into a G-code, which is fed to a 3D printer for part printing.

TOPIC 3: CFD ANALYSIS OF TROMBE WALLS

Unlike traditional walls, Trombe walls are exposed to the sun and used as solar thermal collectors to provide clean energy during cold winters. To analyze the performance of Trombe walls and their characteristics, a commercial CFD package such as SolidWorks is used to carry out the CFD analysis. Theoretical models will then be used to validate the CFD analysis.

TOPIC 4: CHARACTERIZATION OF FLOW AROUND A TIDAL ENERGY PLATFORM

With increasing energy demand, alternative energy sources such as floating tidal energy devices are gaining popularity. The project simulates and investigates water flow around a simplified tidal energy prototype and compares the results obtained to existing data to determine the efficiency and practicability of tidal energy sources.

TOPIC 5: INVESTIGATING THE APPLICATION OF IOT IN AUTONOMOUS AND CONNECTED VEHICLES

The Internet of Things is the connection of devices to the cloud to share data and enhance the users’ experience. Connecting an automobile to the IoT enables autonomous functioning as directions and mapping can be obtained using information collected from sensors. An analysis of IoT as related to automobiles involves analyzing the technologies such as DSRC, radar and 5G used in adaptive cruise control and different automation levels to conclude their pros and cons.

TOPIC 6: EVALUATION OF ALTERNATIVE LIQUID FUELS IN THE INTERNAL COMBUSTION OF AUTOMOBILES

Combustion of fuels, when not efficient, results in pollution and fuel wastage. With increasing sustainability efforts globally, alternative liquid fuels are being adopted. This investigation is done to determine the effect of alternative fuels (such as Di Methyl Ether, methanol and alcohol) on the combustion characteristics of an automobile, the environmental impact through emissions and their compatibility.

TOPIC 7: MANAGEMENT OF ALUMINIUM WASTE

Many products are made of aluminium (from cans to electrical wires), making it the most used metal. This project is aimed at recycling aluminium cans. The process focuses on turning the waste cans into powder. To do this, a low-cost copula mini furnace is designed using SolidWorks software and fabricated to heat aluminium. Atomizers are added to the furnace to create a powder, which is easier to recycle and dispose of.

TOPIC 8: INTERACTION BETWEEN FLUID, ACOUSTICS AND VIBRATIONS

Vibrations determine most designs, fluids power most actuators (pneumatic and hydraulic), and acoustics is how we interact with sound waves. This project focuses on the interaction of these three aspects (creating a vibration on a structural object carrying a fluid creates sound waves) and how they travel and can be harnessed. Understanding this interaction is useful for advancing other fields, such as energy collection and materials.

TOPIC 9: INVESTIGATION OF PHOTOVOLTAIC-THERMAL SYSTEMS FOR BUILDING, HEATING AND POWER SUPPLY

The project is focused on designing and analyzing a PVT system that can be installed in buildings. These units installed in buildings should facilitate driven heat, power generation, and supply. First, a conceptual design of the system will be constructed, followed by computer modelling and optimization of the system and finally, an analysis of the system’s environmental and economic benefits and energy-saving capabilities.

TOPIC 10: QUADCOPTER BLADE DESIGN AND OPTIMIZATION

The CFD method is used to design and optimize the quadcopter blade. ANSYS Workbench (Space Claim and FLUENT) package is used for the CAD design generation as it offers a range of areas where analysis can be carried out on the design. The 3D model of the design of the blade is created using a 3D printer. This design is the prototype that will be used in the analysis and optimization.

TOPIC 11: INVESTIGATION OF ACOUSTIC PERFORMANCE OF AN INDUSTRIAL EXPANSION SILENCER

This is also called a transmission line fitter. In this project, an industrial expansion silencer is designed to effectively block out background noise with an expansion length (L) that peaks at odd quarter-wavelength frequencies and zeros at even half-wavelength frequencies. Additionally, acoustic wave interference phenomena are investigated as it affects the expansion chamber’s performance.

TOPIC 12: INVESTIGATION OF ACOUSTIC PERFORMANCE OF COMBUSTION CHAMBER LINERS

The main cause of combustion noise and, by extension, combustion instabilities (which decrease engine performance, increase vibrations and increase engine failure rate) is the interactions between combustion liners and air flows. An investigation on how to reduce noise levels, increase combustion efficiency and gas turbine combustion chamber lifespan is a much-needed development.

TOPIC 13: DESIGN OPTIMIZATION OF A CENTRIFUGAL PUMP USING CFD

Centrifugal pumps are widely used, requiring optimization for high pressure, high heat and chemically toxic environments. A study on optimizing the centrifugal pump through computational fluid dynamics lowers cavitation and failure rates while in use. For this analysis, the ANSYS workbench is used for simulating and optimizing at saturation points

TOPIC 14: COMBUSTION AND ENERGY SYSTEMS

Combustion is often needed to provide the energy required by various systems. This research aims to identify and improve the relationship between combustion and energy systems.

TOPIC 15: CFD ANALYSIS OF A MASTER CYLINDER

The master cylinder is a major component that determines the performance and efficiency of many machines. In this research project, the master cylinder is designed using CATIA V5 software and analyzed using ANSYS 16.2. Based on stress and pressure responses, a construction material is chosen. The properties of the cylinder are also examined. Finally, its uses in mechanical engineering will be explained.

TOPIC 16: MODELLING THE PROPERTIES OF AND MANUFACTURING A PEARLITIC RAIL STEEL 900A

This study will investigate the potential of modified Pearlitic rail steel of grade 900A in the rail industry. It will examine how the structure’s tensile strength, load capacity, and impact resistance may be altered. Additionally, the RVE model (representative volume elements) is used to determine the impact of the bainitic phase on its properties by identifying its microstructural characteristics.

TOPIC 17: A CFD ANALYSIS OF WELLBORE FLOW BEHAVIOR NEAR A HYDROCARBON RESERVOIR

Fluid flow from a hydrocarbon reservoir to a wellbore is complex as both pressure and flow rates change over time. This research used CFD to understand the radially symmetric flow dynamics from a hydrocarbon reservoir to a wellbore. The nonlinear flow from the wellbore is analyzed using 3D Navier-Stokes equations. Both velocity and pressure are coupled into one system and solved using the algebraic multigrid method. The Darcy model for the reservoir flow and the pressure diffusivity equations are used to verify the CFD. The inflow performance relations curve analyses the flow through the wellbore.

TOPIC 18: DESIGNING OF A DYNAMIC ANKLE FOOT ORTHOSIS

Ankle foot orthoses aid the rehabilitation of feet after suffering from drop foot as it facilitates a range of motion in the ankle joint, including flexion, abduction, extension, and adduction. The customization of this orthosis involves scanning technologies and geometry acquisition, custom designing using 3D software, design and finite element analysis, gait analysis, 3D printing or other additive manufacturing, mechanical testing and functional evaluation. Controllable from a distance, the gadget will use an electric motor to move in the desired direction.

TOPIC 19: DESIGN AND ANALYSIS OF METAL PODS UNDER DEEP SEA

In this research, a remotely operated deep-sea pod used to transport study and exploratory equipment below the ocean surface to its floor is designed using Siemens NX, fabricated using 17-4 PH stainless steel of grade H900 and analyzed using ANSYS workbench.

TOPIC 20: USING CFD TECHNIQUES TO DESIGN AN ENERGY-EFFICIENT HVAC SYSTEM

Heating, Ventilation and Airconditioning systems are central to many structures as they maintain optimal temperatures and ensure air circulation. As these systems consume a lot of energy, this project aims at improving their efficiency. The 3D model is done using SolidWorks, while the CFD simulations are carried out in ANSYS CFX.

TOPIC 21: DESIGN OPTIMIZATION OF A SHELL AND TUBE HEAT EXCHANGER

This study examines how baffles influence heat transmission in a shell and tube design. SolidWorks is used for 3D CAD modelling and ANSYS for CDF analysis.

TOPIC 22: THE STRESS ANALYSIS OF TWIN-SCREW GAS COMPRESSOR’S COMPONENTS

The project aims to determine the stress pattern or characteristics of the different components that make up the twin-screw gas compressor. These patterns are determined by carrying out a finite element analysis of the gas compressor. Once analysis is complete, a more efficient model will be proposed to increase the compressor’s life span.

TOPIC 23: STRESS ANALYSIS ON SCROLL COMPRESSOR COMPONENTS

As a scroll compressor is exposed to pressure and heat deformations while in operation, its structural and mechanical analysis is vital in design and fabrication. In this project, this analysis is carried out using CAE, such as ANSYS and NX. This ensures the optimization of the design.

TOPIC 24: CFD ANALYSIS OF AERODYNAMIC BRAKES IN RACE CARS

The aerodynamic braking system is installed in race cars as a flab attached to the bonnet. The flab is retractable and only operational when braking by increasing the drag force. Detailed analysis of the aerodynamics of a race car in relation to the brake (flab) performance improvement will be carried out using CFD.

TOPIC 25: HOUSE HEATING BY SOLAR ENERGY

House heating in cold regions accounts for up to 30% of the national energy, thus resulting in high carbon emissions for fossil fuel-dependent countries. Solar panels are used to reduce the resultant carbon print. To install a solar home heating system, one needs a simple, cost-effective, easy-to-clean and easy-to-install design.

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