subsea engineering dissertation topics

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Offshore Engineering Topics

by Chess Subsea Engineering · Published April 17, 2015 · Updated November 21, 2016

Chess Subsea Offshore Engineering Research Topics

Our Offshore Engineering research topic includes:

Advanced Subsea Production System (SPS) Professional Courses

Subsea production system is associated with the overall process and all the equipment involved in drilling, field development, and field operation.

Subsea Well Drilling Systems
Wellhead system(s) with associated casing strings
Subsea Christmas trees (XT) for production or injection purposes
Subsea Umbilical Risers and Flowlines (SURF)
Manifolds, Jumpers, Spools, Pipelines and Foundations
Subsea Control Systems (SCS)
Subsea Processing Systems – Boosting, Compressors, Separation & Power

The downloadable PDF below; shows relationship between subsea production systems (SPS) – Field Architecture

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Fundamentals of Oil and Gas Engineering for Graduates and Business Development Resource Personnel’s
Fundamentals of Oil and Gas Offshore Engineering
Fundamentals of Subsea Survey, Positioning & Metrology
Fundamentals of Subsea Engineering
Fundamentals of Subsea Processing Systems – Boosting, Compressors, Separation & Power

Fundamentals of Pipeline Engineering for Engineers

Fundamentals of Subsea Flow Assurance for Engineers

Fundamentals of Subsea Vessels & Lay Equipment

Fundamentals of Subsea Pipelines and Structures Installation Techniques

Fundamentals of Subsea Hoop Up and Field Commissioning – Pipeline Case Study
Fundamentals of Isolation & Intervention Guild lines for Driver Access to Subsea Systems
Fundamentals of Underwater Access Technology – Divers and Diverless
Introduction to Intervention & Workover Systems used in the Subsea Production System Environment
International Standards, Directives & Guidelines for the Subsea Oil & Gas Industry
Application of Mathematical tools used for calculation & Sizing of Topside and Subsea Equipment
Fundamentals of Valves utilized in Subsea Production Systems
Fundamentals of Subsea Umbilicals & Control Lines
Subsea Environment and Basic Corrosion Mechanism
Fundamentals of Offshore Decommissioning & Abandonment
Multiplex Subsea Control BOP Stack – Operations, maintenance, trouble shooting and job hazard analysis
Subsea Well Control Systems

Subsea Distribution System

Subsea Surveying, Positioning, Installation and Foundation
Installation and Vessels

Subsea Cost Estimation

Subsea Control Systems
Supervisory Control And Data Acquisition (SCADA) System (Advanced)
Subsea Power Supply
Subsea Route Selection & Free Spanning
Stress Analysis Based Design of Pipelines
Fundamentals of Pipeline Buckling and Collapse

Fundamentals of Subsea Pipeline Stability
Subsea Systems Materials and Steel Grade Selection
Fundamentals of Subsea Systems Cathodic Protection Monitoring
Pipeline Ancillary Equipments
Pipeline Installation, Commissioning and Decommissioning
Pipeline Failure, Corrosion and Insulation

Subsea Project Execution and Interfaces

Subsea Risk and Reliability

Subsea Corrosion and Scale

Subsea Manifolds – Engineering, Construction & Installation
Pipeline Ends and In-Line Structures – Engineering, Construction & Installation
Subsea Connections and Jumpers – Engineering, Construction & Installation
Subsea Wellheads and Trees – Engineering, Construction & Installation
Subsea Umbilical Systems – Engineering, Construction & Installation
Drilling Risers – Engineering, Construction & Installation
Subsea Production Risers – Engineering, Construction & Installation
Advanced Pipeline Engineering – Construction, Installation and Operations

Chess Subsea Engineering Petroleum Engineering ECourses – Paid

Fundamentals of Siesmic Interpretations
Introduction to Geophysical Data Aquisition
Fundamentals of Geopressure
Introduction to Reservoir Geology
Fundamentals Siesmic Data Processing
Introduction to Structural Geology, Stratigraphy and Geochemistry
Fundamentals of Surface Logging
Fundamentals of Petroleum System Modelling

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Drilling and Completion for Artisans, Field Engineers and Resource Personnel’s
Hoisting, Rotating, Circulating and Mud Treatment Systems
Rig Instrumentations
Casing and Cement Jobs
Well Heads & Assesories
Well Control Equipments
Well Completions & Workover
Well Test Programme Planning
Well Service Activities Planning

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Project Definition, Strategy and Overall Planning
Project Economic Evaluation and Cost Management
Total Project Management
Project Managerial Skills
Project Quality Management
Stress Control Management
Supervisory Skills Management Skills
Total Quality Management
Warehouse Management
Plant Management
Maintenance Activity Management

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Reliability, Availability & Maintainability – RAM

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Process Review and Optimization

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Production Chemistry and Flow Assurance
Multiphase Principles and Simulations

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Chess Subsea Engineering Rotating Machinery ECourse Modules – Paid

Rotating Machinery Engineering

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Chess Subsea Engineering HSE Management ECourses Modules – Paid

Fire and Fire Prevention
Toxic Gases – H2S
Occupational Health
Risk Assessment Documents
Risk Evaluation & Risk Based Inspection
HSE Before Shutdowns, Isolation or Maintenance Work
HSE Management in Exploration and Production
HSE Plan Implementation Activities
HSE Procedures Supervisor

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Chess Subsea Engineering Operations Management ECourse Modules – Paid

Fundamentals of Pipeline Pre-Commissioning Operations Management

Fundamentals of Pipeline Cathodic Protection Operations Management

Introduction to Pipeline Construction Operations Management

Introduction to Pipeline Leak Repair Operations Management

Introduction to Pipeline Pigging Operations Management

Oil & Gas Operations Quality Management for Project Teams

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Introduction to Oil and Gas Contracting Management in Nigeria

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Chess Subsea Engineering Oil Spill Response & Cleanup Courses

Chess Subsea Engineering Dredge Operations Management ECourses – Paid

Introduction to Offshore Dredging Operations Management

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Offshore Systems Decommissioning and Abandonment
Offshore Project Engineering Procurement and Construction (EPC) Management
Subsea Systems Asset Integrity Management
Advanced Subsea Production Control System
Advanced MUX BOP Control System
FMECA of Subsea Control Module System and Sub components
FMECA of Subsea XT System and Sub components
FMECA of Subsea MUX BOP System and Sub equipment
Subsea Production Systems Reliability Engineering (i.e. XT, MUX BOP, SCM, Jumpers, Spools, Risers, Manifolds, SDUs etc.)
Hydraulic Power Unit Reservoir Sizing for Existing and New Field
XT Components Selection

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A brief history of Health Safety Legislation – United Kingdom
Oil and Gas Engineering for Undergraduates, Graduates & Business Development Team
Introduction to Subsea | Offshore EPIC Project Interface
Introduction to Subsea Production Systems
Subsea Production System (SPS) Building Block
Fundamental Building Block of Subsea Processing System
Subsea Equipment Trends | Host Facilities | Installation Vessel | Tree Interface that Govern Design | XT Installation Techniques
Subsea Intervention Operation Vessels
Introduction to Subsea XT – Part 1
Introduction to Subsea XT – Part 2
Introduction to Subsea XT – Part 4
Introduction to Subsea XT – Part 5
Introduction to Subsea XT – Part 6
Introduction to Subsea Xmas Tree (Advanced) – Part 7
Introduction to Subsea Control System – Part 1
Introduction to Subsea Control System – Part 2
Introduction to Subsea Control System – Part 3
Introduction of Subsea Control System – Part 4
Introduction to Subsea Control System – Part 5
Floating Production, Storage and Offloading (FPSO) Facilities
General Specifications for Subsea Systems and Offshore Structures – Part 1
Introduction to System Reliability Engineering
Measurement of System Reliability Part 2
Measurement of System Reliability – Part 3
System Reliability and Risk Management Methodology
System Design for Reliability

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Subsea Production Systems and Top Sides Topic

April 17, 2015

by Chess Subsea Engineering · Published April 17, 2015 · Last modified November 21, 2016

Deepwater Oil and Gas Development

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Offshore Installation and Vessels

Introduction to Oil Spill Response & Clean Up Operations Management

Subsea Umbilical Systems

Subsea Manifolds

Subsea Power Supply Systems

Subsea Production Risers Systems

Fundamentals of Offshore Decommissioning & Abandonment

Deepwater Multiplex Subsea BOP Control System & Marine Riser System

Advance Subsea Production Control System

Fundamentals of Principles of Offshore Hydraulics & Pneumatic Systems – Case Studies Subsea

Oil & Gas Operations Quality Management for Project Teams

ROV Intervention and Interface

Fundamentals of Underwater Access Technology – Divers and Diverless

Subsea Well Control Equipment

Subsea Connections and Jumpers

Subsea Systems Risk and Reliability

Subsea Drilling Risers Systems

Offshore & Subsea Operations Project Design & Planning

Fundamentals of Offshore Engineering

Fundamentals of Oil and Gas Engineering for Undergraduates, Graduates & Business Development Team

Fundamentals of Subsea Hook Up and Field Commissioning – Pipeline Case Study

Subsea Systems Risk Based Inspection

Subsea Survey, Positioning & Metrology

Subsea System Flow Assurance Engineering

Fundamentals of Isolation & Intervention Guidelines for Diver Access to Subsea Systems

Subsea Systems Installation and Vessels Selection

Introduction to Subsea Engineering

Subsea Wellheads and Trees

Subsea Field Development

Pipeline Engineering

Introduction to Subsea Vessels & Lay Equipment

Oil & Gas HSE Management

Supervisory Control And Data Acquisition System

Introduction to Oil and Gas Contracting

Engineering Dissertation Topics

A dissertation (or a final year project report) is a comprehensive technical report of the research work carried out. A dissertation must present some new, original concepts that lead to further research. The core area of a dissertation consists of a hypothesis (or a research question) upon which an investigation is conducted and, in most cases, inevitably leads to further research. A dissertation must be focused, concise and must address the research topics at every level. Also, along with research, a dissertation is expected to present complete evidence of research work in the form of research methods. Sometimes it’s hard to even know where to start. Herein, many engineering research areas, currently being sought after in the industry and academia, are suggested, including electronics, sensors technology, environmental engineering, supply chain engineering, computer science engineering, electrical engineering and civil engineering, to help you start your research.

Electronics and Communication Dissertation Topics

Sensors Technology Dissertation Topics

Environmental engineering dissertation topics, supply chain engineering dissertation topics, supply chain management dissertation topics, computer science engineering dissertation topics, electrical engineering dissertation topics, civil engineering dissertation topics, management related engineering dissertation topics, electronics and communications dissertation topics.

Over the past decade the rise of electronic communication has been revolutionised; it is the fastest growing technology. There are numerous areas of research in this field; however, the most demanding ones are highlighted below.

Defining the boundaries of electrical signals for current electronics (communication) systems.
The limitation of fibre optic communication systems and the possibility of further improving their efficiency.
Developing the embedded communication system for the national grid to optimise energy usage.
Improvement of inter-symbol interference in optical communications.
A study of the various forms of errors and the development of an equalisation technique to reduce the error rates in data.
Gaussian pulse analysis and the improvement of this pulse to reduce errors.
Realising the potential of RFID in the improvement of supply chain.
Radiation in integrated circuits and electronic devices.
Design of high speed communication circuits that effectively cut down signal noise.
Spectral sensing research for water monitoring applications and frontier science and technology for chemical, biological and radiological defence.
Nano-structured membranes for preparative purifications of biopharmaceuticals.

The rise of smart technology has been revolutionising sensor technologies, and there is a high demand to make more efficient and compact sensors. The following topics are a few areas that researchers are currently working in to realise further potentials.

Design and development of a pressure sensor for a solar thermal panel.
An investigation into wind speed and direction sensors to optimise the operations of wind turbines.
Utilising MEMS for profiling airflow around large building structures.
Development of micro sensors to measure oil flow rate in tanks.
Development and implementation of micro sensors to study pressure of the blood stream.
Development of sensors to measure heat generated from solar panels.
Sensing and controlling the intensity of light in LEDs.
Research and computational simulation of a natural olfactory biosensor.
Development of glucose biosensors using nanotechnology.

We are living in the age of technology where the driving force is to reduce the environmental impact of engineering products. Many countries have been undertaking projects supporting the environment and aiming to reduce carbon emissions. The following engineering dissertation topics are of utmost interest for researchers in the industry.

Analysing the impact of aviation industry on the environment and the potential ways to reduce it.
The environmental cost of the so called green energy, ‘wind energy’.
An analysis of factors that hinder the realising of cutting-edge technology for reducing carbon emissions from automobiles.
Design and development of a system for measuring the carbon index of an energy intensive company.
Process improvement techniques to identify and remove waste in the automotive industry.
Process mapping techniques to identify bottle necks for supply chain industry.
A study of compressor operations on a forging site and mapping operations to identify and remove energy waste.
Improving processes to reduce kWh usage and reduce inefficiencies.
Developing a compact device to measure energy use for a household.
In the forging industry how can changing burners within furnaces help organisations achieve energy efficiency?
How can gas consumption be reduced and efficiency introduced to reduce kWh usage?
How can voltage reduction devices help organisations achieve efficiency in electricity usage?
What are carbon credits and how can organisations generate them?
There are some organisations that use water excessively, with bills totalling more than £25,000. Identify the main reasons for such water usage and investigate better ways to introduce water efficiency and create savings.
Identify the ways by which efficient control systems using information systems can be introduced to study the energy usage in a machining factory.
A project to set up ways to measure natural gas flow ultrasonically and identify waste areas.
How can water conductivity probes help determine water quality and how can water be reused?

Supply chain plays an important role in the manufacturing business sector. It is important that the supply chain is well supported by efficient methods and processes. Your engineering dissertation topics could be about:

Highlighting the difference between the supply chain engineering and management for a company to improve output.
Analysing the key factors in process planning and optimisation of supply chain for a manufacturing company.
Developing a supply chain template for a small but thriving online business.
How can organisations achieve success by reducing bottlenecks in supply chain?
Just-in-time – is it really valid? Measurement of losses within just-in-time process implementation.
How can process efficiency be introduced to reduce waste within the manufacturing process?
Supplier relationship is an important factor for the success of just-in-time. How can organisations ensure successful transactions?
Research to identify efficient logistics operations within a supply chain.
Research to introduce efficiency within information systems and support timely transfer of knowledge and information.
The effect of globalisation on supply chain engineering/management for large multi-national companies.
Research studying the impact of culture on supply chain industries: identification of factors that generate inefficiencies with the supply chain.

Supply chain management involves the administration, management, control and supervision of the movement of goods and services from supplier to manufacturer to wholesaler to retailer and to the end consumer. Supply chain management involves coordinating and integrating these elements using an effective and efficient approach and methodology. Supply chain management is important for businesses to ensure there is minimum waste, drive innovation thereby creating integrated value chains. Supply chain management plays an important and central role in the success of a business. Please find a list of topics on supply chain management that may be useful for your engineering dissertation:

A detailed investigation into the need and use of dynamic staff to determine and rectify supply chain problems with a specific focus on the construction industry.
Research into eco-friendly and sustainable practices in supply chain management.
Research to develop a learning organisation and its impact on supply chain management.
Research to measure and develop intellectual capital within the supply chain industry.
A detailed study of innovative forecasting and demand planning strategies for supply chain management
Research study to create measurements to study the impact of learning organisation on performance measurement in supply chain industry
Impact of training on knowledge performance index within supply chain industry.
The behaviour of Carbon index with the implementation of a learning organisation.
Developing a framework for supply chain management in densely populated urban cities
Detailed investigation and analysis taking into account supply chain and logistical strategies for perishable goods.
The influence and impact of emerging e-commerce technologies on supply chain management.

Computer science engineering focuses on the key elements of computer programming and networking with a focus on gaining knowledge of the design, implementation and management of information systems. Information systems play a major role in computer science engineering and an integral component to the successful operations of organisations. The management of information technology systems is a major element for organisations. The following could be used for an engineering dissertation as well as a computing dissertation:

How can organisations ensure that information system is effectively used to maintain process efficiency?
How can learning organisations influence the development of information systems?
The role of risk management in information technology systems of organisations.
Research to identify and reduce e-waste using information technology strategies and systems.
Current status and research on E-waste in the United Kingdom
Development of measurement systems to measure e-waste.
A detailed review of the role of information technology in improving productivity and transforming organisations.
An investigation into the use of information technology as a tool for sustained competitive advantage.
A high-level investigation and detailed review into best practices for the implementation of information technology in modern day organisations.

Electrical engineering is focused on the design, development, testing, supervision and the manufacturing of electrical equipment. Electrical engineers design the electrical systems of automobiles, aircrafts, power generation equipment, communications systems, radar and navigational systems. The design and development of these electrical components are key and central to modern day life. There are several topics within this area that you could research for your electrical engineering dissertation:

Development of a system to study the efficiency of motors in order to reduce kWh usage
Setting up of a control system to monitor the process usage of compressors.
Develop a scheme to normalise compressor output to kWh.
Research to investigate, develop and introduce schemes to ensure efficient energy consumption by electrical machines.
Research to study transformer losses and reduce energy loss.
Research to study metering techniques to control and improve efficiency.
Research to introduce smart metering concepts to ensure efficient use of electricity.
Integration of smart metering pulsed outputs with wireless area networks and access real-time data.
Developing effective strategies and methodical systems for pay as you go charging for electric vehicles
A detailed review and investigation into the key issues and challenges facing rechargeable lithium batteries
Trends and challenges in electric vehicles technologies
Smart charging of electric vehicles on the motorway

The main emphasis of civil engineering in recent times is focused on sustainable development of quality, durable structures that deliver value for money, maximise the benefits from innovation and meets the specifications of the end users. Construction of sustainable houses has been a top priority within civil engineering. The following research topics are being actively undertaken and may be a good area for you to base your research on your own engineering dissertation:

Development of sustainable homes making use of renewable energy sources.
The use of sustainable materials for construction: design and delivery methods.
The role of environmental assessment tools in sustainable construction
The use of warm mix asphalt in road construction
Research to study properties of concrete to achieve sustainability.
Development of waste reduction strategy to achieve sustainable concepts
High-level review of the barriers and drivers for sustainable buildings in developing countries
Research to study the impact of sustainability concepts on organisational growth and development.
Sustainable technologies for the building construction industry
Building Information Modelling in the construction industry
Research regarding micromechanics of granular materials.
Research to study and develop water treatment processes.
Research to set up remote sensing applications to assist in the development of sustainable construction techniques.
High-level strategies, best practice guidelines and methodologies for sustainable construction.
State of the art practice for recycling in the construction industry.
Key factors and risk factors associated with the construction of high rise buildings.
An investigation into health and safety in the construction industry.

Engineering management is the application of the practice of management to the practice of engineering. Engineering management integrates problem-solving, engineering, technological developments and advancements in organizational structure, administrative, and planning abilities of management in order to oversee the operational performance of complex engineering driven enterprises. These two topics go hand in hand and support each other quite well. It is important that both sides are well balanced. The following research topics could be useful for your engineering dissertation:

Steps to conduct management of change to ensure smooth process improvement.
Research to sustainably manage a project team.
Research to study the management of engineering projects and various risks involved with them.
Research to identify process improvement plans to support business strategies.
Efficient supply chain management to ensure and develop key motivational skills within staff members.
How leadership can help efficiency within a learning organisation.
Developing an integrated approach to strategic management in organisations.
Creating and sustaining competitive advantage in engineering organisations.
Developing frameworks for sustainable assessments taking into account eco-engineering measures.
The role of engineers in managing development in emerging countries.

Phaneendra Kondapi Bio:

With more than 20 years of experience managing engineering projects at energy industry giants FMC Technologies and KBR, Phaneendra "Phani" Kondapi brings a unique and invaluable skillset to his role as director of the subsea engineering program.

After serving as director of subsea engineering at Texas A&M University, Kondapi returned to UH in 2017 as the founding director of engineering programs in Katy. In this role, he will spearhead the expansion of UH Engineering programs that are in high demand in Houston's Energy Corridor, including petroleum, subsea, civil, electrical and environmental engineering.

Kondapi, who was instrumental in developing the program, also led efforts to standardize global subsea education through the University's Global Subsea Education Alliance. One of the pioneering instructors in the college's subsea engineering program, Kondapi began teaching the inaugural "Flow Assurance" course at UH in 2011.

He received the 2013 SPE Teaching Excellence Award from the Society of Petroleum Engineers (SPE) International, which recognizes petroleum engineering faculty who have demonstrated innovative teaching techniques and creative pedagogy methods in the classroom. Most recently he received both the SPE Gulf Coast Region 2017 Projects, Facilities and Construction Award and the Distinguished Achievement Award for petroleum engineering faculty.

Kondapi holds a B.S. and an M.S. in chemical engineering from Andhra University in India and a Ph.D. in chemical engineering from Tennessee Technological University.

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Academic literature on the topic 'Subsea engineering'

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Journal articles
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Book chapters
Conference papers

Journal articles on the topic "Subsea engineering":

Lindland, Hans Jorgen. "Overview: Subsea Engineering (August 2000)." Journal of Petroleum Technology 52, no. 08 (August 1, 2000): 36. http://dx.doi.org/10.2118/0800-0036-jpt.

Dimmock, P., E. Clukey, M. F. Randolph, D. Murff, and C. Gaudin. "Hybrid Subsea Foundations for Subsea Equipment." Journal of Geotechnical and Geoenvironmental Engineering 139, no. 12 (December 2013): 2182–92. http://dx.doi.org/10.1061/(asce)gt.1943-5606.0000944.

Marotta, Egidio (Ed). "Analysis LED Design in Subsea Engineering." Mechanical Engineering 137, no. 03 (March 1, 2015): S8—S12. http://dx.doi.org/10.1115/1.2015-mar-7.

Yasseri, Sirous. "Evidence-based practice in subsea engineering." Underwater Technology: International Journal of the Society for Underwater 32, no. 4 (March 1, 2015): 231–44. http://dx.doi.org/10.3723/ut.32.231.

King, Gregory W. "Drilling Engineering for Subsea Development Wells." Journal of Petroleum Technology 42, no. 09 (September 1, 1990): 1176–83. http://dx.doi.org/10.2118/18687-pa.

Lu, Junfu, and Xiaoqiang Xue. "Research on he Classification of Life-Cycle Safety Monitoring Levels of Subsea Tunnels." Polish Maritime Research 24, s2 (August 28, 2017): 125–32. http://dx.doi.org/10.1515/pomr-2017-0074.

Yasseri, Sirous. "Application of systems engineering to subsea development." Underwater Technology 32, no. 2 (July 1, 2014): 93–109. http://dx.doi.org/10.3723/ut.32.093.

Bijker, E. W. "Advances in Subsea Pipeline Engineering and Technology." Coastal Engineering 17, no. 3-4 (August 1992): 285–89. http://dx.doi.org/10.1016/0378-3839(92)90057-2.

Franchek, Matthew A. "Project Atlantis." Mechanical Engineering 137, no. 03 (March 1, 2015): S4—S7. http://dx.doi.org/10.1115/1.2015-mar-6.

Chen, Bao Yan, Meng Lan Duan, Ming Zeng, Shi Chao Lu, Zhuo Liu, Tong He, and Ming Jie Li. "Testing Technology of Subsea Christmas Tree." Advanced Materials Research 591-593 (November 2012): 2523–26. http://dx.doi.org/10.4028/www.scientific.net/amr.591-593.2523.

Dissertations / Theses on the topic "Subsea engineering":

Molloy, Paul. "Smart materials for subsea buoyancy control." Thesis, University of Glasgow, 2000. http://theses.gla.ac.uk/6161/.

Greenlee, Alison S. "Design of subsea energy storage chamber." Thesis, Massachusetts Institute of Technology, 2009. http://hdl.handle.net/1721.1/54471.

Micheletti, David (David Mark) 1979. "Design of position sensors for subsea oil tools." Thesis, Massachusetts Institute of Technology, 2003. http://hdl.handle.net/1721.1/87866.

Dynge, Martin Steen-Nilsen. "Subsea Permanent Magnet Motor with Damper winding." Thesis, Norges teknisk-naturvitenskapelige universitet, Institutt for elkraftteknikk, 2014. http://urn.kb.se/resolve?urn=urn:nbn:no:ntnu:diva-27238.

Thiraviam, Amar Raja. "Accelerated life testing of subsea equipment under hydrostatic pressure." Doctoral diss., University of Central Florida, 2010. http://digital.library.ucf.edu/cdm/ref/collection/ETD/id/4525.

Ambler, Charles Kirby. "Design of an underwater vertical glider for subsea equipment delivery." Thesis, Massachusetts Institute of Technology, 2010. http://hdl.handle.net/1721.1/58391.

Stølan, Ronny. "Losses and Inductive Parameters in Subsea Power Cables." Thesis, Norwegian University of Science and Technology, Department of Electrical Power Engineering, 2009. http://urn.kb.se/resolve?urn=urn:nbn:no:ntnu:diva-9992.

Four samples of galvanized steel armour for sub sea power cables are tested with an electric steel tester. The samples exhibit diﬀerent remanence magnetization and permeability. The eﬀects of permeability on loss in sub sea cables is found to be insigniﬁcant. Slight increase of conductor inductance due to increase in permeability of armour wires is observed. Mutual cancellation of inductance between circuits that are twisted opposite to each other, or with respect to one circuit, is conﬁrmed with laboratory tests and measurements on full scale sub sea power cables. The parameters of one cable is calculated using IECs analytical approach and found to be inaccurate for conductor resistance. The Calculations places 22% of total cable loss in the armour. Measurements on two sub sea cables and analysis using ﬁnite element method contradict the calculated armour loss. Parameters for two sub sea power cables are calculated based on measurements performed on the actual cables. The calculated values are compared with values computed using ﬁnite element analysis. Derived physics from laboratory experiments and measurements on the cables is applied in ﬁnite element analysis and found to be accurate compared with calculated values from measurements and computed values using Flux 2.5D.

Bourgeois, Desmond. "Hydrogen Assisted Crack in Dissimilar Metal Welds for Subsea Service under Cathodic Protection." The Ohio State University, 2015. http://rave.ohiolink.edu/etdc/view?acc_num=osu1437668334.

Schlegelmilch, Tye (Tye Anthony). "The design of a coiled tubing cutter for use in subsea oil drilling applications." Thesis, Massachusetts Institute of Technology, 1999. http://hdl.handle.net/1721.1/38278.

Valentini, Francesco. "Experimental and numerical study of methods to displace oil and water in complex pipe geometries for subsea engineering." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2019. http://amslaurea.unibo.it/17528/.

Books on the topic "Subsea engineering":

Bai, Yong. Subsea engineering handbook . Burlington, MA: Gulf Professional Pub., 2010.

Bai, Yong. Subsea engineering handbook . Burlington, MA: Gulf Professional Pub., 2012.

Palmer, Andrew C. Subsea pipeline engineering . 2nd ed. Tulsa, Okla: PennWell Corporation, 2008.

Ellinas, C. P., ed. Advances in Subsea Pipeline Engineering and Technology . Dordrecht: Springer Netherlands, 1990. http://dx.doi.org/10.1007/978-94-009-0617-4.

Subsea International '85 (1985 London, England). Design and installation of subsea systems: Proceedings of an international conference (Subsea International '85) . London: Graham & Trotman, 1985.

ASPECT, '94 (1994 Aberdeen Scotland). ASPECT '94: Advances in subsea pipeline engineering and technology. Dordrecht: Kluwer Academic, 1994.

Papusha, Alexander N. Beam theory for subsea pipelines: Analysis and practical applications . Hoboken, New Jersey: John Wiley & Sons, 2016.

Ellinas, C. P. Advances in Subsea Pipeline Engineering and Technology: Papers presented at Aspect '90, a conference organized by the Society for Underwater Technology and held in Aberdeen, Scotland, May 30-31, 1990 . Dordrecht: Springer Netherlands, 1990.

Palmer, Andrew C., and Roger A. King. Subsea Pipeline Engineering . Pennwell Books, 2004.

Subsea Engineering Handbook . Elsevier, 2019. http://dx.doi.org/10.1016/c2016-0-03767-1.

Book chapters on the topic "Subsea engineering":

Duan, QingFeng. "Subsea Connector." In Encyclopedia of Ocean Engineering , 1–6. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-10-6963-5_224-1.

Du, Zunfeng, and Haiming Zhu. "Decommissioning of Subsea Facilities." In Encyclopedia of Ocean Engineering , 1–6. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-10-6963-5_169-1.

Tong, F., and T. Griffiths. "Hydrodynamics for Subsea Systems." In Encyclopedia of Ocean Engineering , 1–7. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-10-6963-5_235-1.

Wang, Yingying. "Subsea Equipment Installation Technology." In Encyclopedia of Ocean Engineering , 1–11. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-10-6963-5_222-1.

Alien, K. P., and A. W. Crawford. "Improving Subsea MPI Consistency." In Advances in Underwater Technology, Ocean Science and Offshore Engineering , 189–97. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-4203-5_22.

Liu, Guijie. "Remotely Operated Vehicle (ROV) in Subsea Engineering." In Encyclopedia of Ocean Engineering , 1–13. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-10-6963-5_225-1.

da Silva Ribeiro, Luiz Henrique Marra, Leonardo de Padua Agripa Sales, and Rodrigo Batista Tommasini. "Uncertainty Quantification in Subsea Lifting Operations." In Lecture Notes in Mechanical Engineering , 139–49. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-53669-5_11.

Nesse, E. W., H. Lindland, R. Husebye, and K. Höglund. "Wellman: the Subsea Intervention System." In Advances in Underwater Technology, Ocean Science and Offshore Engineering , 215–22. Dordrecht: Springer Netherlands, 1988. http://dx.doi.org/10.1007/978-94-009-1299-1_24.

Kogo, Bridget, Bin Wang, Luiz Wrobel, and Mahmoud Chizari. "Residual Stress Simulations of Girth Welding in Subsea Pipelines." In Transactions on Engineering Technologies , 389–403. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-0746-1_30.

Neffgen, J. M. "Advances in Flexible Pipe Design and Construction." In Advances in Subsea Pipeline Engineering and Technology , 111–43. Dordrecht: Springer Netherlands, 1990. http://dx.doi.org/10.1007/978-94-009-0617-4_6.

Conference papers on the topic "Subsea engineering":

Balk, Wouter F., and Kees Tjeenk Willink. "Subsea Hydrocarbon Processing and Treatment: Twister Subsea." In ASME 2011 30th International Conference on Ocean, Offshore and Arctic Engineering . ASMEDC, 2011. http://dx.doi.org/10.1115/omae2011-49199.

Eyre, G. P., A. Day, Robin Galletti, and John Ray. "Engineering the DEEPSEP Subsea Boosting System." In Offshore Technology Conference . Offshore Technology Conference, 1995. http://dx.doi.org/10.4043/7739-ms.

Cheldi, T., C. Chimisso, and M. Marangoni. "Engineering Integration for Frontier Subsea Development." In European Petroleum Conference . Society of Petroleum Engineers, 1996. http://dx.doi.org/10.2118/36875-ms.

Baker, Jason, Patrick Ferraioli, Luis R. Pereira, Abram Hudson, Gregg Barton, Sagar Bhatt, Matt Fritz, and Ryan Odegard. "Requirements Engineering for Retrofittable Subsea Equipment." In 2016 IEEE 24th International Requirements Engineering Conference (RE) . IEEE, 2016. http://dx.doi.org/10.1109/re.2016.44.

King, G. W. "The Drilling Engineering for Subsea Development Wells." In SPE/IADC Drilling Conference . Society of Petroleum Engineers, 1989. http://dx.doi.org/10.2118/18687-ms.

Kawaguchi, Katsuyoshi, Eiichiro Araki, Sho Kaneko, Takato Nishida, and Tetsuya Komine. "Subsea engineering ROV and seafloor observatory construction." In 2011 IEEE Symposium on Underwater Technology (UT) and Workshop on Scientific Use of Submarine Cables and Related Technologies (SSC) . IEEE, 2011. http://dx.doi.org/10.1109/ut.2011.5774090.

Heier, Espen, and Tore Mellem. "Pipeline Subsea Repair." In ASME 2007 26th International Conference on Offshore Mechanics and Arctic Engineering . ASMEDC, 2007. http://dx.doi.org/10.1115/omae2007-29274.

Gullaksen, Joannes. "Software Application Based on Subsea Engineering Design Codes." In ASME 2020 39th International Conference on Ocean, Offshore and Arctic Engineering . American Society of Mechanical Engineers, 2020. http://dx.doi.org/10.1115/omae2020-18063.

Deka, Dhyan, Mark Cerkovnik, Nikhil Panicker, and Vamsee Achanta. "Subsea Jumpers Vibration Assessment." In ASME 2013 32nd International Conference on Ocean, Offshore and Arctic Engineering . American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/omae2013-11011.

Ratnayake, R. M. Chandima, T. Garten, and A. Barre. "Subsea Systems Functional Failure Consequence Classification: A Case Study From a Subsea Manifold." In ASME 2015 34th International Conference on Ocean, Offshore and Arctic Engineering . American Society of Mechanical Engineers, 2015. http://dx.doi.org/10.1115/omae2015-41522.

Reports on the topic "Subsea engineering":

Kress, Marin, David Young, Katherine Chambers, and Brandan Scully. AIS data case study : quantifying connectivity for six Great Lakes port areas from 2015 through 2018 . Engineer Research and Development Center (U.S.), May 2021. http://dx.doi.org/10.21079/11681/40720.

Skills & Innovation

Introduction to Subsea Engineering

Online Learning Course.

Are you new to subsea?

Looking to increase your knowledge of the sector or get up to speed on new developments?

A deeper understanding of subsea...

Whether you’re a new graduate engineer, an ambitious business development executive or a seasoned engineer from another sector, this course will equip you with deeper knowledge of subsea and a recognised certificate on completion.

Global Underwater Hub’s Introduction to Subsea Engineering course is designed to provide an in-depth understanding of the industry which will give you a strong foundation for developing your career.

With a focus on subsea developments, the course is fully developed by industry for industry professionals. It is regularly updated to ensure that the material is relevant and addresses current trends within the sector.

With 40-60 hours of interactive material, learn at your own pace over an 8-week period.

Delivered online by Robert Gordon University, the course has four modules which will extend your knowledge of the sector. Each of the four modules covers relevant industry topics that cover everything you will ever need to know in whatever your chosen field.

Formation of Oil and Gas
Exploration and Worldwide Production
History of the North Sea
Offshore Extraction and Processing
Transportation and Downstream Processing
Current Legislation Applicable in the UKCS
Subsurface Engineering
Drilling and Well Engineering
Operating Facilities
Operational Aspects
The Subsea Industry
An Example of Subsea Development
Future Development for the Industry
Subsea Completions
Subsea Control Systems
Flow Assurance
Pipeline Fundamentals
Installation of Equipment
Subsea Production Umbilicals and Power CablesRisers and Topsides
Current and Developing Systems

I studied business management at university, and no prior engineering or subsea knowledge, or any knowledge of the offshore industry. This online course was extremely helpful in creating a foundation of basic knowledge of the industry and engineering for which I can then build on going forward.

Commercial Graduate, DeepOcean

The content and layout of the course is excellent and the way you are tested ensure s you read all the material, ensuring a guaranteed learning experience. I would highly background looking for a general understanding of Subsea Engineering.

Senior Document Controller, Subsea 7

IPD - If you are planning to apply for registration this course may help provide you with evidence towards meeting some of the UK SPEC IMechE competence requirements.

CPD - This course can contribute to your CPD and ongoing IMechE reflective learning.

Cullen College of Engineering > Department of Mechanical Engineering / Department of Petroleum Engineering > Petroleum and Subsea Engineering, MS

First of Its Kind Dual Degree Program in the World

Graduate students interested in the related fields of Petroleum Engineering and Subsea Engineering can combine their studies in a Dual Petroleum/Subsea Master’s degree program. The dual degree program allows students to obtain both a master’s degree in Petroleum Engineering and a master’s degree in Subsea Engineering completing 45 credit hours of relevant graduate coursework. Hence, with the appropriate selection of graduate course within the Petroleum Engineering department and Subsea Engineering program, students can be awarded both degrees, thereby significantly reducing the total number of credit hours needed if the two degrees were pursued separately. This dual degree potentially broaden students’ horizons by studying in the two programs. It will also enhance their network and the chances of landing a successful job.

Admission Requirements

New students may apply to the Petroleum or Subsea Engineering graduate program for admission and indicate their interest to pursue the dual Petroleum/Subsea MS degree. To be unconditionally admitted to the Dual MS program, an applicant should have:

A Bachelor’s degree in Petroleum Engineering or in a related engineering field.
A grade point average of at least 3.00 out of 4.00 exclusive of grades received for activities such as seminars, physical education, industrial internships, etc.
An adequate score on the Graduate Record Examination (GRE).
A minimum score of 6.5 on the IELTS or 79 on the TOEFL iBT examination for students who do not meet the UH English Language policy.
Three letters of recommendation attesting to the student’s capacity to perform in the classroom. A minimum of two letters should be from faculty members who have observed the academic performance of the applicant, and one can come from an engineering industry supervisor.
A statement of purpose that is consistent with the areas of instruction.

Acceptance to the program is based on a competitive combination of academic background, GRE scores, recommendation letters and the statement of purpose.

Students may begin their graduate studies in one program and apply for admission to the dual degree program at a later date. However, the decision by a student to pursue the dual degree should be made prior to the completion of 18 hours of coursework or a maximum of one year into one of the degree programs.

Program of Study

Within the 45.0 completed credit hours, students must fulfill the program requirements for each separate degree, and leveling and pre-requisite courses, if applicable. Hence, the course selections should simultaneously comply with the course requirements of the Petroleum Engineering MS program and the core area course requirements of the Subsea Engineering MS program.

Petroleum and Subsea engineering are closely related fields as many of the subsea oil and gas processes and systems overlap with petroleum engineering disciplines. There is a need to understand the concepts of petroleum engineering in designing the subsea systems and hence sharing courses makes the student understand many basics of the subjects. For example, reservoir engineering, drilling, production operations, etc. are shared by both engineering disciplines. Hence many of the courses can be shared that are mutually related to each program. Outside the program elective is an optional course between both the programs and that can be shared.

Degree Requirements

Credit hours required for this degree: 45.0

Program of Study for the Dual MS Program without Thesis

Minimum twenty one credit hours of approved coursework from PETR required courses and advanced elective courses, excluding leveling courses, if applicable.
Minimum twenty one credit hours of coursework from the approved Subsea Engineering courses excluding pre-requisite courses, if any.
Three credit hours of approved relevant coursework (optional elective) at the 6000-level or above can be from within the College of Engineering with prior approval from the Program Directors.

Graduation Requirements

To graduate, students must meet UH and the Cullen College of Engineering graduate requirements.

The students enrolled in the Dual Degree program will be continuously monitored and underperforming students will be carefully advised. The students should do well in both programs. The students will have to be qualified to get admission into individual programs (PETR and SUBS) and those who qualify will be given admission to Dual Master’s program.

In a rare case, if the students underperforms in one of the programs but does well in the other program, then the student has to withdraw from the program where he/she is performing poor but can continue in the other program as if it is an individual program and has to meet the separate program requirements.

Approved Course List

Petr courses, required courses (four courses).

PETR 6302 - Reservoir Engineering II Credit Hours: 3.0
PETR 6312 - Well Log Evaluation of Petroleum Formations Credit Hours: 3.0
PETR 6368 - Well Drilling and Completion I Credit Hours: 3.0
PETR 6372 - Petroleum Production Operations Credit Hours: 3.0

Elective Courses (minimum three courses)

PETR 6304 - Core Analysis of Petrolem Formations Credit Hours: 3.0
PETR 6308 - Advanced Petroleum Production Operations Credit Hours: 3.0
PETR 6310 - Petroleum Production Economics Credit Hours: 3.0
PETR 6314 - Pressure Transient Testing Credit Hours: 3.0
PETR 6316 - Well Drilling and Completion II Credit Hours: 3.0
PETR 6318 - Horizontal Drilling Credit Hours: 3.0
PETR 6320 - Enhanced Oil Recovery Processes I Credit Hours: 3.0
PETR 6325 - Integrated Reservoir Characterization Credit Hours: 3.0
PETR 6326 - Applied Reservoir Simulation Credit Hours: 3.0
PETR 6332 - Deterministic Reserves Estimation Credit Hours: 3.0
PETR 6336 - Petroleum Energy Markets Credit Hours: 3.0
PETR 6350 - Natural Gas Engineering Credit Hours: 3.0
PETR 6374 - Artificial Lift Credit Hours: 3.0
Or any new PETR course approved by the Program Director

SUBS Courses

Required courses (three courses).

SUBS 6305 - Mathematics for Subsea Engineers Credit Hours: 3.0
SUBS 6310 - Flow Assurance Credit Hours: 3.0
MECE 6334 - Convection Heat Transfr Credit Hours: 3.0

Elective Courses (minimum four courses)

SUBS 6320 - Riser Design Credit Hours: 3.0
SUBS 6330 - Pipeline Design Credit Hours: 3.0
SUBS 6340 - Subsea Process and Artificial Lift Credit Hours: 3.0
SUBS 6350 - Subsea Controls and System Engineering Credit Hours: 3.0
SUBS 6351 - Design of Subsea Blowout Preventers Credit Hours: 3.0
SUBS 6360 - Subsea Materials and Corrosion Credit Hours: 3.0
SUBS 6370 - Computational Methods & Design Experiments Credit Hours: 3.0
SUBS 6380 - Subsea Systems Credit Hours: 3.0
SUBS 6397 - Selected Topics Credit Hours: 3
Design for Oil and Gas
Advanced Flow Assurance
Additional Topics
Or any new SUBS course approved by the Program Director

Academic Policies

University of Houston Academic Policies
Graduate Academic Policies: Cullen College of Engineering

Graduate Degree Programs

The department offers the following graduate programs for full-time and part-time students:

with thesis in Mechanical Engineering. This program focuses on engineering science in one of several areas of specialization. A formally defended thesis describing research into a topic of current academic interest is the centerpiece of this program.
without thesis in Mechanical Engineering . The focus of the non-thesis program can be varied between engineering science and engineering practice through a selection of elective courses from the Colleges of Engineering, Natural Science and Mathematics, Business, and Law.

Master of Mechanical Engineering (MME) is a non-thesis, 10-course graduate curriculum that is designed as a professional degree. This program provides depth of knowledge in selected areas of mechanical engineering, as well as broader knowledge in other engineering, science, business or law topics.

Master of Science in Subsea Engineering is a non-thesis, 10-course graduate curriculum.

Dual M.S. Degree in Mechanical and Aerospace Engineering The dual degree program allows students to obtain both a master’s degree in Mechanical Engineering and a master’s degree in Aerospace Engineering completing 45 credit hours of relevant graduate coursework.

Dual M.S. Degree in Aerospace Engineering and Space Architecture A dual degree program that allows students to obtain both a master's degree in aerospace engineering and a master's degree in space architecture by completing 46 credit hours of relevant graduate coursework.

Dual M.S. Degree in Mechanical and Subsea Engineering

Doctor of Philosophy (Ph.D.) in Mechanical Engineering in several areas of specialization. The Ph.D. is the highest degree granted by the University and its possession signifies that the holder has demonstrated the ability to perform original research. The student's principal objective is to produce a dissertation that can be considered a significant contribution to the field of knowledge in mechanical engineering. Our standard Ph.D. program assumes a completed M.S. degree prior to admission. Our Direct Admit program allows the exceptional student to be admitted to doctoral candidacy without a completed M.S. degree.

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Momentum Magazine

Hydrogen: From Production to Market
Carbon Capture, Utilisation and Storage
Offshore Wind Power Cable Management
Offshore Wind
Subsea Power Cables
Harnessing Hydrogen Fuel Cells for a Sustainable Future
Subsea Systems and Hardware
Design of Subsea Pipelines
Further Design of Subsea Pipeliens
Subsea Appreciation
Subsea Pipelines
Integrity Management of Subsea Pipelines
Integrity Management Flexibles and Risers
Integrity Management: Lessons Learned
Offshore Remedial Works
Pigging and Plugging
Planning and Executing Subsea Intervention
Subsea Controls
Subsea Project Delivery
Subsea Project Management
Corrosion Defect Assessment
Cost and Schedule Estimation for Subsea Projects
Installation Calculations for Subsea Pipelines
Installation Analysis of Subsea Structures and Sea-Fastenings
On-Bottom Stability
Lifetime Extension of Rigid Pipelines and Flexibles
Navigating Energy Transition: A Comprehensive Guide for the Investment Community
Construction of Subsea Pipelines
Decommissioning Programme Development and Execution
Dynamic Riser Analysis
Freespan Assessment

Top 5 Challenges for Subsea Engineering in 2023

Kate Aguilera Dec 20, 2023 10:26:24 AM

Deepwater Operations: As oil and gas reserves continue to decline in shallower waters, subsea engineers are increasingly operating in deep and challenging environments. This requires new and innovative technologies to ensure the safe and efficient operation of subsea equipment.
Extreme water depth: the technical and operational difficulties of operating at great depths.
Subsea infrastructure: the design and deployment of subsea infrastructure, including pipelines, umbilicals, and subsea equipment.
Remote operations: managing remote subsea operations, including monitoring, maintenance, and repair.
Real-time data: collecting and analysing real-time data to inform decision-making and improve operations.
Robust communication: establishing and maintaining robust communication systems for subsea operations.
Regulatory compliance: complying with regulations and standards, such as those set by the IMO and OGP.
Technological innovation: keeping up with technological innovations and advancements in subsea engineering.
Decommissioning: planning and executing the decommissioning of subsea infrastructure, including pipelines and wells.
Collaboration: fostering effective collaboration between subsea engineers, operators, and other stakeholders.
Risk management: managing risks associated with subsea operations, including safety, environmental, and financial risks.
Decommissioning and Abandonment: With many subsea assets reaching the end of their operational lives, subsea engineers face the challenge of safely and efficiently decommissioning and abandoning these assets.
Technological advancements: leveraging new technologies, such as robotics, automation, and artificial intelligence, to enhance the efficiency and safety of decommissioning operations.
Environmental concerns: addressing increasing environmental concerns and regulations related to oil rig decommissioning.
Cost reduction: finding ways to reduce the costs of decommissioning, including reuse and recycling of materials.
Increased collaboration: fostering increased collaboration between oil companies, regulators, and environmental groups to drive better outcomes for all stakeholders.
Decommissioning planning: integrating decommissioning planning into the design and construction of new oil rigs to minimize future costs and environmental impacts.
Offshore wind: considering opportunities to repurpose decommissioned oil rigs for offshore wind energy production.
Renewable energy: exploring the potential of decommissioned oil rigs as sites for renewable energy production, such as wave and tidal energy.
Data management: improving data management and sharing to enhance transparency and collaboration in the decommissioning process.
Public perception: improving public perception of decommissioning activities and addressing public concerns related to environmental impacts and costs.
International cooperation: promoting international cooperation to standardize decommissioning practices and reduce costs and environmental impacts.
Increasing Complexity: With the increasing sophistication of subsea systems, subsea engineers must stay up to date with the latest technologies and design practices to ensure the safe and efficient operation of these systems.
Integration of new technologies: incorporating new technologies, such as artificial intelligence, big data analytics, and the Internet of Things, into subsea systems.
Remote operations: increasing the use of remote operations and autonomous systems to enhance the efficiency and safety of subsea activities.
Cybersecurity: addressing the increasing threat of cyber-attacks on subsea systems and ensuring their security and reliability.
Maintenance and repair: developing new methods for the maintenance and repair of subsea systems, including the use of robotics and autonomous vehicles.
Data management: improving data management and analysis to enhance decision-making and performance optimization in subsea systems.
Collaboration: fostering increased collaboration and knowledge sharing among stakeholders in the subsea industry to drive innovation and efficiency.
Subsea digital twin: utilising subsea digital twin technology to simulate and optimise subsea systems and operations.
Integration of renewable energy: exploring the integration of renewable energy sources, such as wave and tidal energy, into subsea systems.
Deepwater exploration: expanding deepwater exploration and production activities, including the development of new technologies and systems to support these operations.
Regulatory compliance: complying with increasingly complex and stringent regulations related to subsea systems and operations.
Cost Management: With the ongoing challenges faced by the oil and gas industry, subsea engineers must find ways to reduce costs while maintaining safety and operational efficiency.
Technological advancements: leveraging new technologies, such as robotics, automation, and artificial intelligence, to reduce costs and increase efficiency in subsea engineering.
Integrated project planning: incorporating cost management into the planning and design phase of subsea engineering projects to reduce costs and mitigate risks.
Data analytics: utilising data analytics to improve decision-making and optimise cost management in subsea engineering.
Supply chain management: optimising supply chain management to reduce costs and improve the efficiency of subsea engineering projects.
Collaboration: fostering increased collaboration among stakeholders in the subsea industry to drive innovation, reduce costs, and optimise performance.
Standardisation: promoting standardisation of subsea engineering practices and technologies to reduce costs and improve efficiency.
Life cycle management: integrating life cycle management into subsea engineering projects to optimise cost and performance over the life of the infrastructure.
Decommissioning planning: incorporating decommissioning and abandonment planning into subsea engineering projects to minimize future costs and improve cost management.
Risk management: incorporating risk management into cost management processes to mitigate risks and reduce costs.
Cost transparency: increasing cost transparency and reporting to improve accountability and cost management in subsea engineering.
Environmental Protection: As public concern over the environmental impact of offshore activities grows, subsea engineers must find ways to minimise the impact of their operations and ensure compliance with regulations and industry standards.
Minimising the impact of subsea operations on marine life and habitat
Reducing greenhouse gas emissions from subsea equipment and vessels
Proper disposal of subsea waste and materials
Prevention of oil spills and other forms of pollution
Minimising noise pollution from subsea equipment and vessels
Protecting sensitive and vulnerable areas, such as coral reefs and deep-sea habitats.

Subsea engineers play a critical role in the exploration and production of oil and gas, and these challenges highlight the need for ongoing training and development to ensure the safe and efficient operation of subsea systems.

Subsea Cable Integrity Management: Ensuring Safe and Efficient Operations for the Life of the Farm

Definition of Subsea Pig Launching and Receiving Capability

Advancements in Subsea Systems and Hardware: Unlocking the Potential of Offshore Operations

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The Best Mechanical Engineering Dissertation Topics and Titles

Published by Carmen Troy at January 5th, 2023 , Revised On August 18, 2023

Introduction

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

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 of our team , so you can trust 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 , along with 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 step by step guide on how to write your own dissertation here.

2022 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 of 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 on 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?

Mechanical Dissertation Topics of 2021

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 atomizers 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

Best Mechanical Dissertation Topics of 2021

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 the years 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 under different current strengths. Results from previous tests already carried out 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 Properities Dissertation Topics

Topic 13: studying the mechanical and durability property 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. 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). The surface damage, along with fiber breakage, will be noted among all three fibers. The effects of the abrasions on all three fibers 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 optimization under the risk. This will save time and allow the designer to obtain new information in regards to the stability of the performance of his design under the 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 with the ability to be recycled are then further examined for potential use as a 3-dimensional printing material. The temperature of the printer’s nozzle along with the nozzle velocity matrix from previous experiments is used to evaluate the tensile strengths 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 defected 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 in 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 articular, 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, 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 the 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 adds 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: 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 regards to 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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Intensification of evaporation of uranium hexafluoride

Chemical Engineering Science and Chemical Cybernetics
Published: 14 August 2013
Volume 47 , pages 499–504, ( 2013 )

Cite this article

A. M. Belyntsev 1 ,
G. S. Sergeev 2 ,
O. B. Gromov 2 ,
A. A. Bychkov 1 ,
A. V. Ivanov 2 ,
S. I. Kamordin 3 ,
P. I. Mikheev 4 ,
V. I. Nikonov 2 ,
I. V. Petrov 1 ,
V. A. Seredenko 2 ,
S. P. Starovoitov 1 ,
S. A. Fomin 1 ,
V. G. Frolov 1 &
V. F. Kholin 2

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The theoretical mechanism of the sublimation of uranium hexafluoride are considered. The most contribution to the rate of evaporation of UF 6 is introduced by the conductive mode of heat exchange. Various modes of the intensification of the evaporation of uranium hexafluoride during the nitrogen supply in pulse mode to the product mass are investigated. The nitrogen supply results in the turbulization of gas flow within a vessel (Re = 2500–4000) and significantly increases the rate of evaporation of uranium hexafluoride with the substantial decrease in a weight of the nonevaporable residue of 5.6–1.0 kg. The complex application of the pulse nitrogen supply in combination with heating the bottom of the vessel is the most effective method for evaporating uranium hexafluoride. The rate of evaporation of UF6 increases by a factor of almost four in comparison with the design mode. The developed methods are applied in industry and provide the stable operation of Saturn reactors during the conversion of uranium hexafluoride into its dioxide.

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Production of Uranium Hexafluoride with Low 234U Content in a Cascade with Intermediate Product

V. A. Palkin

Plasma-Chemical Treatment of Process Gases with Low-Concentration Fluorine-Containing Components

H. S. Park, S. P. Vaschenko, … D. Yu. Batomunkuev

Obtaining Hydrogen Fluoride During the Interaction of Uranium Hexafluioride with Hydrogen and Oxygen in a Combustion Regime. Experiment

D. S. Pashkevich, Yu. I. Alekseev, … V. V. Kapustin

Gromov, B.V., Vvedenie v khimicheskuyu tekhnologiyu urana (Introduction to Uranium Chemical Technology), Moscow: Atomizdat, 1978.

Google Scholar

Sergeev G.S. Study of the evaporation of uranuym hexafluoride from solid and liquid phases and ways of intensifying this process, Cand. Sci. (Eng.) Dissertation , Moscow: All-Union Research Inst. of Chemical Technology, 1970.

Lykov, A.V., Teoriya sushki kapillyarno-poristykh kolloidnykh materialov pishchevoi promyshlennosti (Theory of Drying of Capillary-Porous Colloid Materials of the Food Industry), Moscow: Gostekhizdat, 1948.

Sushkin, I.N., TeplotekhnikaF (Heat Engineering), Moscow: Metallurgiya, 1973.

Morachevskii, A.G. and Sladkoe, I.B., Fizikokhimicheskie svoistva molekulyarnykh neorganicheskikh soedinenii. Spravochnik (Physical and Chemical Properties of Molecular Inorganic Compounds: A Handbook), Leningrad: Khimiya, 1987.

Katz, J. and Rabinovich, E., The Chemistry of Uranium , New Yorl: McGraw-Hill, 1951.

Kasatkin, A.G., Osnovnye protsessy i apparaty khimicheskoi tekhnologii , (Fundamentals of Chemical Engineering Science), Noscow: Khimiya, 1971.

Bychkov, A.A., Nikonov, V.I., Seredenko, V.A., et al., Industrial tests and commercialization of fluorohydrocarbon evaporation from 1 m3 cylinders using nitrogen pulsing into the cylinder, in Sb. rabot MSZ i OAO VNIIKhT , (Collected Papers of MSZ and VNIIKhT), Moscow, 2005.

Petrov, N.V., Bychkov, A.A., Sergeev, G.S., et al., RF Patent 2264987, 2005.

Petrov, N.V., Bychkov, A.A., Seredenko, V.A., et al., RF Patent 2326053, 2008.

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Engineering Works, Elektrostal’, Moscow oblast, Russia

A. M. Belyntsev, A. A. Bychkov, I. V. Petrov, S. P. Starovoitov, S. A. Fomin & V. G. Frolov

Leading Research Institute of Chemical Technology, Moscow, Russia

G. S. Sergeev, O. B. Gromov, A. V. Ivanov, V. I. Nikonov, V. A. Seredenko & V. F. Kholin

Bochvar All-Russia Research Institute of Inorganic Materials, Moscow, Russia

S. I. Kamordin

Bauman Moscow State Technical University, Moscow, Russia

P. I. Mikheev

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Original Russian Text © A.M. Belyntsev, G.S. Sergeev, O.B. Gromov, A.A. Bychkov, A.V. Ivanov, S.I. Kamordin, P.I. Mikheev, V.I. Nikonov, I.V. Petrov, V.A. Seredenko, S.P. Starovoitov, S.A. Fomin, V.G. Frolov, V.F. Kholin, 2011, published in Khimicheskaya Tekhnologiya, 2011, Vol. 12, No. 11, pp. 675–681.

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Belyntsev, A.M., Sergeev, G.S., Gromov, O.B. et al. Intensification of evaporation of uranium hexafluoride. Theor Found Chem Eng 47 , 499–504 (2013). https://doi.org/10.1134/S0040579513040040

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Received : 25 January 2011

Published : 14 August 2013

Issue Date : July 2013

DOI : https://doi.org/10.1134/S0040579513040040

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uranium hexafluoride
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30 Best universities for Mechanical Engineering in Moscow, Russia

Updated: February 29, 2024

Art & Design
Computer Science
Engineering
Environmental Science
Liberal Arts & Social Sciences
Mathematics

Below is a list of best universities in Moscow ranked based on their research performance in Mechanical Engineering. A graph of 269K citations received by 45.8K academic papers made by 30 universities in Moscow was used to calculate publications' ratings, which then were adjusted for release dates and added to final scores.

We don't distinguish between undergraduate and graduate programs nor do we adjust for current majors offered. You can find information about granted degrees on a university page but always double-check with the university website.

1. Moscow State University

For Mechanical Engineering

2. Bauman Moscow State Technical University

3. National Research University Higher School of Economics

4. Moscow Aviation Institute

5. N.R.U. Moscow Power Engineering Institute

6. National Research Nuclear University MEPI

7. National University of Science and Technology "MISIS"

8. Moscow Institute of Physics and Technology

9. Moscow State Technological University "Stankin"

10. RUDN University

11. Moscow Polytech

12. Moscow State University of Railway Engineering

13. Finance Academy under the Government of the Russian Federation

14. Moscow Medical Academy

15. Russian State University of Oil and Gas

16. mendeleev university of chemical technology of russia.

17. Russian National Research Medical University

18. Plekhanov Russian University of Economics

19. National Research University of Electronic Technology

20. Moscow State Pedagogical University

21. Russian Presidential Academy of National Economy and Public Administration

22. State University of Management

23. Moscow State Institute of International Relations

24. Russian State Geological Prospecting University

25. russian state agricultural university.

26. New Economic School

27. Moscow State Technical University of Civil Aviation

28. Russian State University for the Humanities

29. Russian State Social University

30. Moscow State Linguistic University

Universities for Mechanical Engineering near Moscow

Engineering subfields in moscow.

Victor Mukhin

Victor Mukhin, Speaker at Chemical Engineering Conferences

Victor M. Mukhin was born in 1946 in the town of Orsk, Russia. In 1970 he graduated the Technological Institute in Leningrad. Victor M. Mukhin was directed to work to the scientific-industrial organization "Neorganika" (Elektrostal, Moscow region) where he is working during 47 years, at present as the head of the laboratory of carbon sorbents. Victor M. Mukhin defended a Ph. D. thesis and a doctoral thesis at the Mendeleev University of Chemical Technology of Russia (in 1979 and 1997 accordingly). Professor of Mendeleev University of Chemical Technology of Russia. Scientific interests: production, investigation and application of active carbons, technological and ecological carbon-adsorptive processes, environmental protection, production of ecologically clean food.

Title : Active carbons as nanoporous materials for solving of environmental problems

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Mechanical Dissertation Topics of 2021. Topic 1: Mini powdered metal design and fabrication for mini development of waste aluminium Cannes and fabrication. Topic 2: Interaction between the Fluid, Acoustic, and vibrations. Topic 3: Combustion and Energy Systems. Topic 4: Study on the Design and Manufacturing.
Intensification of evaporation of uranium hexafluoride
Gromov, B.V., Vvedenie v khimicheskuyu tekhnologiyu urana (Introduction to Uranium Chemical Technology), Moscow: Atomizdat, 1978. Google Scholar . Sergeev G.S. Study of the evaporation of uranuym hexafluoride from solid and liquid phases and ways of intensifying this process, Cand. Sci. (Eng.) Dissertation, Moscow: All-Union Research Inst. of Chemical Technology, 1970.
Active carbons as nanoporous materials for solving of environmental
Catalysis Conference is a networking event covering all topics in catalysis, chemistry, chemical engineering and technology during October 19-21, 2017 in Las Vegas, USA. ... Victor M. Mukhin defended a Ph. D. thesis and a doctoral thesis at the Mendeleev University of Chemical Technology of Russia (in 1979 and 1997 accordingly). ...
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Below is the list of 30 best universities for Mechanical Engineering in Moscow, Russia ranked based on their research performance: a graph of 269K citations received by 45.8K academic papers made by these universities was used to calculate ratings and create the top. ... database with 98,302,198 scientific publications and 2,149,512,106 ...
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The Best Mechanical Engineering Dissertation Topics and Titles

Introduction

2022 Mechanical Engineering Research Topics

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

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

Topic 4: Investigating 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

Covid-19 Mechanical Engineering Research Topics

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

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

Damage caused by Coronavirus to supply chain of manufacturing industries

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

Mechanical Dissertation Topics of 2021

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

Topic 3: Combustion and Energy Systems.

Topic 4: Study on the Design and Manufacturing

Topic 5: Revolution in the Design Engineering

Best Mechanical Dissertation Topics of 2021

Topic 2: The Engineering Applications of Mechanical Metamaterials.

Topic 3: The Mechanical Behaviour of Materials.

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