Over the past few decades transdisciplinary (TD) has been the subject of increased discourse in the context of large, complex, ill-defined, ‘wicked’ problems. However, there has been less consideration of the potential it offers within the practice of engineering. Edison will research how to create tools which enable effective TD working within the automotive sector. The Mobility Engineering 2030 FISTA White Paper identifies that changes within the sector mean that interdisciplinary working, involving groups formed from people working in similar disciplines, will not be sufficient. It recognises that in the future there will be a need for transdisciplinary working, which goes beyond the academic disciplines to understand the societal context. For example, legislation, standards, culture. However, achieving effective TD working within organisations is not simple. It requires the creation of tools (e.g. processes and methods) which enable clear communication and knowledge transfer within and beyond an organisation. Edison's PhD will leverage input from the TREND (TRansdisciplinary ENgineering Designers) £1.8m platform grant (Dec 2017 – Dec 2022). The over-arching aim of TREND is to provide tools to assist engineers to work in a transdisciplinary manner and to identify the types of engineers that are transdisciplinary. Identifying what makes engineering teams in the automotive sector transdisciplinary and how to assess their current readiness level to be transdisciplinary is the focus of Edison's PhD activity. Edison's PhD will have a particular focus on ‘common’ characteristics and automotive design team behaviour within and across industry case studies. Mapping findings at various life cycle stages such as designer requirements, use of digital tools etc. for each case study/domain against the manufacturing life-cycle phases. This would be followed by cross case-study analysis. The analysis may use techniques such as input/output system modelling to map the designer requirements at each stage of the manufacturing life cycle, and/or socio-technical analysis could be used to classify and model the designer behaviour. In summary Edison will be required to create a structured framework to estimate the automotive sectors transdisciplinary readiness level. Specific objectives may include 1. Undertake a literature review to understand the state of TD working within the automotive sector. 2. Engage with stakeholders to gather information which informs the design of the TD readiness tool. 3. Create a TD readiness tool. 4. Validate the proof of concept tool within industry.
Electric vehicles (EVs) play a key role in decreasing the carbon footprint of the mobility sector. Their high upfront cost, limited range and slow charging speed are however a barrier to increased EV uptake. Reducing the cost and improving the EV Lithium-ion (Li-ion) battery could reduce these barriers. There is however limitied knowledge in the safe operation and degradation rate of Li-ion batteries. This is largely due to the complex electrochemical mechanisms not being well understood. Furthermore, the large operating envelope (temperature, charging speed etc.) over its lifetime require resource intensive testing to parameterize semi-imperical models. The battery is therefore operated very conservatively, resulting in oversizing the battery and sub-optimal operating conditions resulting in inefficiencies and higher costs. Johannes' PhD aims to provide optimal testing strategies and accurate modelling of Li-ion batteries in order to provide information to facilitate more efficient operating strategies (e.g. fast charging). This will be achieved by a combination of advanced design of experiments (DOE), modelling and machine learning.
The initial part of Johannes' PhD will focus on building a model structure which is based on a semi-physical neural network. The accuracy of this model will then be assessed using existing battery data in literature and data provided by the industrial parter. An experimental test campaign will then be designed and implemented, in an attempt to efficiently parameterize the battery models. The resultant battery models would then provide important information to improve the safe operation range of the battery.
Electric machines are becoming more prevalent in the automotive industry as they become the main propulsion system in road vehicles with the industry’s shift towards emissions free mobility. With over 15% of new car sales being electric, being able to accurately characterise electric machines virtually is imperative for maximising their performance and efficiency. A key predictor of a model’s ability to replicate transient behaviour is the accuracy of the parameters used to characterise the motor. Relying solely on the information and specifications provided by the manufacturer to create a robust model is impractical as they often only include information required for the machine’s operation. The overarching aim of this work is to develop a procedure to automate the parameterisation of electric motor models for later use in the vehicle development process.
There are many potential use cases for motor models, and many motor architectures of interest. In each combination of use case and motor architecture, the appropriate motor model structure is expected to differ. Typically, the level of spatial and temporal resolution will increase when more insight into detailed motor performance is needed. Once a model structure is defined, the data required to parameterise and validate this model can be defined. Then, the experiments necessary to generate this data, along with the instrumentation required can be defined. Focusing on the model development of electric machines, this project aims to create an end to end workflow between model and data to increase model accuracy and adaptability to new units under test. The work will explore the potential for a general motor model and parameterisation procedure that is compatible with all the likely motor topologies of interest: flux switching, induction, and synchronous motor architectures. It will focus on implementing an autonomous parameter characterisation process, and on streamlining the experimental procedure behind the collection of data required for the parameterisation of an electric machine.
Batteries vary in density as they undergo charging and discharging and recent work demonstrated that ultrasound can identify these material mechanical changes permitting the level of charge to be measured. Our research considers taking this approach and implement it to automotive batteries to maintain continuous in-service charge and structural health monitoring.
Lithium-ion battery cells are regarded as one of the key drivers to sustainability for future transportation solutions. Hence, applying charge monitoring using ultrasound will make battery cells even more interesting. Current techniques used to measure the battery state of charge (SOC) include tracking the battery voltage and currents but the method lacks efficiency and accuracy. In contrary, ultrasound allows the battery SOC to be measured directly at any time and being not charge history dependent means that errors are not carried on successive measurements. This way we will provide more accurate battery SOC readings, improve battery range estimation, and preserve its structural integrity.
Previously, ultrasound charge monitoring was successfully demonstrated on an individual cell under a laboratory environment. The changes in elastic properties and density of the lithium-ion battery vary the wave speed travelling through the test cell. The wave speed is measured by kowing the time taken by the longitudinal wave to traverse the cell and is used to then determine the battery SOC. Automotive batteries contain several cells stacked together, therefore this research explores how various ultrasonic techniques can be applied to multiple cells within a battery module and how this might constrain module design. In a laboratory environment, a built-in test system will be incorporated to gather data ready to be successively analysed using analysis techniques in signal processing and numerical modelling in predictive machine learning. As a starter, the equipment will comprise of an ultrasonic pulse-generator, ultrasonic probes, a built-in custom test bed, and an individual lithium-ion cell prior to moving on with a multiple cells stacked in series.
What is also motivating us to conduct ultrasonic non-destructive evaluation is to provide a more in-depth understanding of the complex electrochemical characteristics of lithium-ion batteries. This means that our ultrasonic techniques will be closely linked with internal mechanical changes that fluid-filled porous media go through under specific events. In this case, we will also advance a logical understanding of the porousmechanics of solids filled with liquid (i.e., lithium-ion battery cell wet in a liquid electrolyte) and investigate the acoustofluidic phenomena with the use of modern, accurate, and cost-effective lenses.
Dwindling fossil fuel supplies and global warming mean there is an urgent need to develop biorenewable replacements for the petrochemical based fuels and lubricants consumed by the automotive industry. Bioethanol from fermentation of lignocellulose biomass and other high energy biofuel replacements derived from hydrogenated vegetable oils have been developed, however many of these biofuels have low densities and volumetric heating values.
Terpenes represent an alternative class of naturally occurring hydrocarbons which have comparatively higher densities that make them ideal-fuel replacements/additives. Nature produces an estimated one billion tonnes of terpene annually, which is a sufficient volume to consider using these hydrocarbons as replacement biofuels. Recent developments in industrial biotechnology have also demonstrated the potential of engineering metabolic pathways into microbes for the industrial production of economically important higher terpenes. The cheapest commercial sources of terpene currently available is Crude Sulfate Turpentine (CST) which is produced as a waste by-product of the Kraft paper pulp process (approx. 240,000 tonnes p/a) and gum turpentine (110,000 tonnes p/a) that is available from sustainable tapping of pine trees. Both turpentine sources are comprised of a mixture of cyclic monoterpenes (-pinene, -pinene, 3-carene and limonene), that are currently used as chemical feedstocks by the flavour/fragrance industries or burnt on-site to provide a cheap energy source for the pulping plant.
We have recently developed a catalytic two-step ring fragmentation/hydrogenation protocol to convert CST into a ‘sulfur free’ p-menthane biofuel containing controllable amounts of aromatic p-cymene. The monocyclic saturated branched ring structure of p-menthane means that it should exhibiy excellent automotive biofuel properties (high energy, branched, resistant to oxidation, low freezing point, non-carcinogenic). Aaron's project will optimise the chemical route from untreated industrial CST (e.g. desulfurisation technology, catalyst recycling) obtained from a Swedish paper mill (Södra) to produce p-menthane/p-cymene blends (ratio dependent on partial hydrogen pressure) whose combustion performance (e.g. melting point, cloud point, cetane level, temperature performance, combustion kinetics/pathways) will then be optimised to enable field tests to be carried out in different types of combustion engine.
Dmitry's research project aims to build a high-fidelity immersive driving simulator at IAAPS to enable research on topics such as autonomous driving, vehicle driver pedestrian interactions, real-world efficiency and emissions.
The planned driving simulator will be software and hardware agnostic, with the ability to easily upgrade the hardware setup to support motion platforms and 360° projection screens. A framework for processing and fusing multi-sensor data will be created to convert map and real-world captured data into virtual validation routes and scenarios. Uniquely it will be possible to connect the driving simulator to a powertrain dynamometer to allow hardware-in-the-loop control of a physical vehicle or subsystems thereof as an alternative to full vehicle simulation.
The simulator is expected to include the following critical components and systems:
Model interface system
Allowing seamless transfer of data between a variety of different software and hardware platforms that might be linked together as part of the driving simulator.
The model interface layer is the most critical component of the simulator, allowing different components to easily communicate with one another and increasing the ease of commercial collaboration
Vehicle model system
Plug-in based system allowing full vehicle simulation (e.g. via Simulink or CarMaker) through to physical vehicle interface on powertrain-dyno (via AVL Pump)
Driving route and scenario generation pipeline
Using a combination of map and in-vehicle captured data sources
Generation of roads and surrounding scenery, including road markings
Traffic characterisation data to be fed to traffic model (see below)
Traffic modelling and traffic signal simulation
Plugin-based to allow use of existing tools (e.g. SUMO) as well as development of agent-based systems and combinations of micro and macro simulations
Display and rendering system
Enable use of different display/rendering packages (e.g. CarMaker, OpenDS, rfPro)
Scalable display output system (e.g. single monitor to multiple projector systems)
User input and human-machine interface system
Allowing use of different user input devices (from keyboard to gaming steering wheel and pedals to full vehicle CAN-based input systems)
Allowing use of different HMI systems for dashboard and in-vehicle systems (from on-screen generated through to CAN-interfaced physical dashboard)
The project will interact with other research centres (CAMERA CENTAUR) and CDTs (ART-AI) within the university.
Knowing the torque produced by an electric motor is essential in a wide range of applications. In electric vehicles it is important to deliver the torque requested by the driver, and it becomes very important for good drivability when blending regenerative braking torque with the hydraulic brakes. It is a crucial information for the ECU control systems that ensure the drive unit does not exceed battery power limits. It is also a key information when testing and evaluating new motor developments on a dynamometer.
The torque produced by an electric motor is a function of the phase current, and this is commonly used to estimate the motor torque. Unfortunately this simplistic estimation is prone to significant error, which compromises the usefulness of the information. Drivability may be adversely affected, additional safety margin may need to be taken to protect the battery (reducing its effective power density), and in dynamometer applications use of a torquemeter is invariably necessary to ensure the accuracy of the test data. For the dynamometer case, high-accuracy torquemeters are extremely expensive, especially as motor speeds increase beyond 30,000rpm, and also introduce mechanical installation problems due to rotordynamics. The inaccuracy of the estimated torque is due to a wide range of factors including electrical losses, mechanical losses and varying magnet temperature, for example.
This PhD will aim to understand in detail the torque generation (electromagnetic and reluctance torques) as well as all of the loss mechanisms in an electric motor, and to design a reliable and accurate estimate of motor torque. It will be supported by AVL GmbH, the world's largest independent company for the development, simulation and testing of all types of powertrain systems. The initial case study will be a highly instrumented prototype of one of AVL’s next-generation PMSM dynamometer motors, though other applications may also be considered. The research has a strong application focus, and you will have the opportunity to direct the experimental work needed to understand the motor torque. This may take place at IAAPS in Bristol, at AVL in Graz (Austria), or a combination of both.
Outcomes from this PhD will directly contribute to new AVL software upgrades, and their aim is to develop a system which is accurate enough that a torquemeter is no longer essential for dynamometer testing. The findings will be directly applicable to other applications, including control of electric vehicle traction machines.
In undertaking this PhD you will join a team of researchers within the Institute for Advanced Automotive Propulsion Systems (IAAPS), including over 60 other PhD students from a range of disciplines all working in automotive research. You will have direct links with engineers from the project partner, AVL, and will benefit from working alongside another PhD student working on a sister AVL project focussing on thermal modelling of electric machines.
This project would suit a student with a background in Electrical or Mechanical Engineering.Enquire now
Development of propulsion systems for any type of vehicle involves enormous amounts of testing at a range of levels, from components through to whole vehicles. The electrical energy consumption of these test systems is not negligible and can become very significant for long-term experimental campaigns, such as battery degradation or powertrain durability studies. In addition, when there are multiple Units Under Test (UUT) being tested at the same time the peak power requirements can become very high (the sum of all the UUTs), which forces a need for a very large power supply. These two issues lead to increased capital investment costs, higher running costs and larger CO2 footprint.
A great deal of work has been done to optimise component sizing and energy management in hybrid-electric vehicles, but these techniques have never been used to optimise the testbed, which is what this research will explore.
This PhD seeks to understand to what extent energy management strategies can be used to optimise the simultaneous testing of multiple components. It will be supported by AVL GmbH, the world's largest independent company for the development, simulation and testing of all types of powertrain systems. The initial case study will be AVL’s next-generation 36-channel battery cell tester, and other applications may also be considered. Within this battery cell tester an Active Front End is used to maintain a shared DC-link at an elevated voltage, and each channel uses a step-down DC-DC converter to reach a voltage close to the cell voltage. By optimising the power scheduling of the 36 channels, and by recirculating power between channels, the objective is to reduce the system complexity and cost whilst simultaneously improving the energy efficiency of its testing.
The research has a strong application focus and the opportunity to evaluate solutions in hardware with the support of AVL. The outcomes will directly contribute to new AVL software upgrades and inform future generations of powertrain test systems, reducing the cost and CO2 footprint of developing new powertrains.
In undertaking this PhD, you will join a team of researchers within the Institute for Advanced Automotive Propulsion Systems (IAAPS), including over 60 other PhD students from a range of disciplines all working in automotive research. You will also have direct links with engineers from the project partner, AVL.
This project would suit a student with a background in Electrical Engineering; candidates with a background in Mechanical Engineering or IMEE with appropriate experience would also be considered.Enquire now
To achieve net zero by 2050, the IEA have stated that 50% of the technology required is yet to be developed, thus, rapid testing and development in all sectors is required. Increased intensity of testing could however have a significant impact on energy demand, which conflicts with a transition to a renewable energy system. The automotive industry continues to support, and in many instances grow, an already carbon intensive transport sector; despite lulls during the COVID-19 pandemic and increased electric vehicle sales, road transport still equates to around 28% of global carbon emissions. Therefore one area of focus to support the required decarbonisation of the automotive sector, whilst allowing new low-carbon technology to be developed, is associated with increasing the efficiency and efficacy of the testing phase of vehicle technology development.
Physical testing is time consuming due to real-time constraints and complex and technologically delicate systems, and is thus, highly energy intensive. Additionally, human-errors in set up, faulty or mis-calibrated sensors, or unforeseen mechanical failures are often only identified post-test and result in these tests being redundant and needing to be repeated. Virtual testing environments play a role in minimising these tests, allowing simulations to be run earlier in the development process and for more use-cases to be considered. However, if not provided with robust physical data, these models will not be able to accurately simulate hardware responses - they therefore still rely on physical testing for the test data used to adapt and optimise the virtual models. Some physical testing will also still be required for technology to be suitable for market release to account for product variance, unknown effects and simulation inaccuracies.
As the general change of the powertrain development process makes it harder to compensate poor measurement quality by engineering experience, anomaly detection – a method of finding unexpected patterns in data - presents a possible solution to minimise physical testbed time whilst increasing the reliability of real data to feed into virtual simulation models. If applied to a range of powertrain units, be it internal combustion engine, pure electrical drive, fuel cell or hybrid setup, it has the potential to reduce the energy intensity of vehicle testing and development, whilst simultaneously increasing the speed at which low-carbon technologies can be released into the public domain to aid large scale decarbonisation of the transport sector.
A Bill of Materials (BoM) is a document that lists all of the components and resources needed to build a product, in this case a vehicle. Each car has around 15,000 components. If any of these components are missing or incompatible the factory cannot build the vehicle. The problem is made more complex because vehicle makers offer an almost infinite variety of model variations and customisation options. Each of these needs a complete and accurate BoM if the manufacturing process is to succeed. Therefore, each BoM must be validated to ensure it is correct before the vehicle can be built. Techniques exist to automate this validation process, but there is still a heavy reliance on expert knowledge to ensure that nothing is missed or duplicated.
Using AI techniques, it may be possible to understand the variant configuration of each buildable combination and thus eradicate miss-builds and provide vehicle makers with the good information across the whole product line-up which will allow for more accurate planning in terms of assembly as well as financial control. There is a rich dataset of historical BoMs available which can be used to help with this process, as well as access to human experts whose knowledge may able to be represented in an automated procedure. It is likely that the most effective approach will combine these two approaches.
Lois’s PhD seeks to understand the reasons why certain groups of people may or may not accept climate transport policies, specifically looking at Clean Air Zones and Liveable Neighbourhoods. Her work will adopt a mixed-methods approach, combining quantitative, qualitative and machine-learning methods to determine which groups face barriers to acceptance, why, and finally – how acceptance can be facilitated amongst a diverse population.
Water droplets placed on a surface heated to a sufficient temperature (the Leidenfrost temperature) levitate on a film of their own vapour. A recent Nature article showed that adding a sawtooth pattern to the heated surface causes these levitating droplets to be propelled (even uphill!). Very recent work at Bath has shown that this propulsion can be achieved in mm diameter enclosed pipes. This opens the way to exploitation of Leidenfrost propulsion for active cooling systems that operate without moving parts and use waste heat energy for the thermal pumping effect. Onur's project will seek to extend this work by using AM techniques to created 3D printed cooling systems with internal ratchet microstructures. Work will focus on optimum fluid/surface choices (experiments have previously been confined to water) and ensuring AM quality is sufficient to reliably allow propulsion as surface roughness can cause an increase in the Leidenfrost temperature. The effect of pressure on heat transfer will be studied both experimentally and numerically and set in context against current systems.
Immanuel's project investigates a pathway to making water injection for combustion engines mass market proof. Water injection for combustion engines has been implemented a number of times into limited production motor vehicles to enable higher engine performance, mainly with forced induction. In these cases, the technology was used to lift the knock limit by decreasing combustion temperatures. However, water injection enables better thermal efficiency with lower combustion temperatures which can decrease particulate, CO, CO2 and HC emissions together with fuel consumption. Nowadays, a large portion of engines utilise forced induction which at certain times requires extra cooling where the engine is made to run rich. Having lower combustion temperatures removes this need. Furthermore, as mentioned, with lower combustion temperatures, engines could run higher compression ratios which would make engines smaller, hence reducing rotational masses and improving fuel consumption. These potential benefits reflect the current drive toward more efficient and cleaner combustion engines. Electrification is one of the pathways being implemented to fight global warming but combustion engines are set to be part of the majority of drivetrains available in the next few decades. One of the reasons why water injection has not made its way into mass production vehicles is the need for the consumer to refill the water tank after relatively short intervals with distilled water from the grocery store. This is impractical and not acceptable for consumer satisfaction. This project aims to produce a solution where the water vapour in the exhaust gas is condensed to liquid form, cleaned and stored to then be injected back into the engine to result in a closed cycle. There are several issues that need to be addressed when proposing such a solution. Among those are water pH values, moulding, freezing and impurities within the condensed water.
Through the sponsoring company, a natural non-toxic additive is in development and may be used for the purpose of the project to potentially eliminate some of the issues with closed cycle water injection. The proposed solution should then be capable to run several thousand kilometres without a refill of the additive, similar to the AdBlue principle in diesel engines. Depending on the progress of the research, a prototype of the whole system is possible where a side effect of the water injection may be that the currently imposed GPF filter for gasoline engines could be removed due to water injection reducing the particulate emissions. This would be a positive side effect since less aftertreatment would result in a weight and efficiency benefit.
With electrification being one of the biggest potential disruptors in modern transport, there is a growing need for lightweight, reliable and efficient thermal management systems. Conventional solutions will struggle to keep future powertrain and propulsion systems cool without incurring significant mass penalties. In addition, future systems are likely to be highly complex, which may also negate the performance benefits. Recovering waste heat will also be a priority to reach desired overall system efficiencies – affecting both the environment as well as operational economics. Advancements in additive manufacturing technologies combined with mathematical/parametric modelling enable the construction of radically different heat exchangers. These units can be designed to reflect their function and application in particular environments. In this PhD, Edgar will focus on engineering methods development to design and validate high-effectiveness, additively manufactured heat exchangers. This research will consider both analytical and experimental techniques. A modular approach is proposed with a focus on heat transfer through thin-walled components and balancing the trade-off between effectiveness and pressure drop across the unit. Finally, Edgar's project will consider further integration with computational intelligence or optimisation techniques in order to radically accelerate the development of complex heat exchangers.
Batteries based on carbon fibre reinforced plastic (CFRP) have the potential to supply power with an improved overall efficiency (vehicle power to weight rather than battery power to weight) compared to current battery technologies. By integrating batteries into the structure in the form of CFRP, lightweighting is not only achieved from the change in material but also from the removal of the non-structural dead weight of conventional batteries and their casements. For example, in automotive applications, structural batteries achieve a 26% theoretical mass saving over use of separate systems for energy storage and load carrying. The current state-of-the-art in structural batteries is a half-cell based on a structural cathode. Significant work is required before a full cell can be manufactured and expected to sustain loading for multiple discharge and mechanical load cycles. Three projects are suggested which focus on challenges at different length scales this is project A:
Fibre matrix interface scale - Battery concepts and fibre electrolyte electrical connectivity: Rob's PhD will focus on both creation and development of new structural battery concepts and on the dual role of the supporting matrix. The matrix must both mechanically support the fibre, for which complete wetting of the fibre by the matrix is optimal, and allow ion migration, for which partial wetting of the fibre, in some battery constructions, is optimal as it allows liquid electrolyte to be in contact with the electrically conductive carbon fibre electrodes. The interface between the fibre and resin is subject to interface chemistry including sizing/functionalisation of the carbon fibres and processes which can control the wetting of the fibres by the matrix. Exploration of both will be key to Rob's PhD.
Batteries based on carbon fibre reinforced plastic (CFRP) have the potential to supply power with an improved overall efficiency (vehicle power to weight rather than battery power to weight) compared to current battery technologies. By integrating batteries into the structure in the form of CFRP, lightweighting is not only achieved from the change in material but also from the removal of the non-structural dead weight of conventional batteries and their casements. For example, in automotive applications, structural batteries achieve a 26% theoretical mass saving over use of separate systems for energy storage and load carrying. The current state-of-the-art in structural batteries is a half-cell based on a structural cathode. Significant work is required before a full cell can be manufactured and expected to sustain loading for multiple discharge and mechanical load cycles. Three projects are suggested which focus on challenges at different length scales this is project A:
Atom-scale modelling, anode development and charging rates/battery cycling: Thomas' PhD project focuses on optimising the construction of the anode of a Carbon Fibre Reinforced Polymer structural battery (with the cathode and electrolyte interface being investigated at Chalmers University in Sweden) and assessing its performance under load. Thomas' work will be undertaken in atomic modelling of the anode and the change in ion migration pathways as the anode is stretched by intercalation (absorption) of ions and mechanical loading. The work will focus on the electrochemical aspects of anode development and leave mechanical aspects to the other projects.
Alex's research will investigate a new concept of free-piston engine for which a patent has been applied for by the University. This concept (known as “ISOTOPE-X”) is mainly intended to function as a range extender for a battery electric vehicle. The project will investigate the performance of the machine firstly as a combustion engine, including possibilities afforded by the flexibility of the piston motion, to in turn establish the requirements placed on the electrical components, and then secondly model these to gauge the feasibility of the whole device. Control requirements will also be studied, including the potential benefit of using “bounce chambers” for instantaneous energy requirement reduction, and the use of pumping chambers for scavenging air supply the cylinders.
The combustion modelling will include the possibility to vary the compression ratio and so investigate the feasibility of using some form of compression ignition to further improve efficiency and reduce emissions. Heat transfer effects will be quantified as part of establishing the losses and also the magnitude of the thermal challenge passed to the magnets of the electrical machine.
It is anticipated that an initial conceptual design will be modelled and that as the analysis progresses and new insights are gained that updates to the design will be incorporated at various stages.
A significant potential avenue is the investigation of hydrogen as a fuel for the machine, since with advanced combustion modes enabled by variable compression ratio it is possible that this combination could be effectively zero emission and more efficient than a fuel cell for heavy duty applications, while being cheaper too.
Elisabetta's PhD will explore the use of solid oxide fuel cells (SOFCs) for the direct conversion of hydrogen storage vectors such as ammonia to electrical energy. SOFCs have several advantages over PEM, including, multi-fuel capability, resilience to poisoning from fuel impurities and lower use of precious metal catalysts.
Chemical molecules such as ammonia have the potential to be excellent hydrogen storage vectors for aviation fuels. They do not require high pressure containment but still achieve very high hydrogen storage densities arising from the hydrogen stored within their chemical structure. However release of the hydrogen requires a catalytic conversion and ppm levels of ammonia are a poison for PEM fuel cells so a SOFC is required.
The project proposes the (1) characterisation and (2) optimisation of SOFCs for usage in aerospace electric propulsion applications. Characterisation of the cells will focus on cycle efficiency of different fuels (Ammonia, hydrocarbons, H2) and the internal chemistry/catalysers used. Optimisation will be on structural weight reduction, power transfer efficiency, and thermal management of waste heat using AM.
WP1: Exploration of Fuel Cell topology / architecture / fuel: To investigate the most suitable fuel, catalyst and electrolyte performance and topology for aerospace applications. Bath already has equipment required to quantify the conversion efficiencies of the cells while some will be purchased directly as part of the project.
WP2: Integrated thermal management: This will investigate different materials and 3D geometries to highly integrate cells and their thermal management making use of extensive simulations. AM heat exchangers and cell components will be prototyped and tested. This will include consideration of fast start-up capability by application of direct radio-frequency heating.
WP3: Technology demonstrator: a prototype SOFC stack to be produced to demonstrate feasibility.
Our streets are shared by multiple types of user. At the extremes, vulnerable pedestrians might occupy urban spaces with vastly more dangerous heavy goods vehicles. Such interactions introduce many disparities and asymmetries in terms of the ability of one party to harm another, and the extent to which each party is legally and physically regulated. A key issue is how these different classes of road user can effectively communicate with one another. This becomes more pressing as we consider the possibility of future autonomous vehicles, which entirely lack a human component and so might communicate very differently (e.g., they are unlikely to interpret informal signals the way a human driver would). All this takes place within a built environment which is regulated by a legal system and surrounded by cultural influences such as news and mass media. Catherine's PhD will look at how communication between road users currently takes place and how people, policy and engineering might be changed to facilitate and improve this.
Optimum lubrication and low-friction in automotive applications represents a potential for reduced energy consumption and emissions in engines. Moving engine components operate under high-temperature and high-pressure conditions where oil additives activate to form sacrificial protective tribo-films, which in turn reduce friction and wear.
Ciaran’s synthetic tribo-chemistry based PhD will focus on the design, synthesis, characterisation and tribo-testing of new inorganic molecules designed to form wear resistant and low-friction films at points within the internal combustion engine where friction and wear cause significant problems.
Virtualisation of complex automotive propulsions systems represents an indispensable requirement for effectively overcoming engineering challenges encountered in their development cycle. State of the art models enable engineers to build high fidelity virtual prototypes as well as simulations capable of offering a realistic operating environment, leading to effective investigations into system behaviour and reducing the efforts associated with physical experiments.
Depending on the structure and complexity, robust effective models require a significant amount of resources during their development to maximise the amount of information describing the physical system. One vital step during this process is the parametrisation of the model selected which may present itself as costly and time-consuming due to the computational power and expert knowledge required. This type of process is also often devised only for a specific application by incorporating assumptions shaping a readily available dataset or acquisition routine, limiting the repeatability of the process relative to measurement data. These shortcomings increased the demand for automated procedures effective in creating virtual representations.
The main aim of Vicentiu's PhD project is to develop robust parametrisation procedures maximising model accuracy while reducing efforts by efficiently using information specific to the system and model structure employed. The initial use-case targeted is represented by battery systems, while others are set to follow and benefit from techniques that have already been employed by the project. The ideal outcome is represented by a demonstrated automated methodology capable to produce optimally parametrised models for given requirements, recognized by a set of Key Performance Indicators (KPIs) targeting the validity and quality of the parametrisation, while reducing testbed as well as computational effort.
It is expected that Vicentiu will produce a prototype implementation of the final methodology and demonstrate this in the prototype factory at the new Institute for Advanced Propulsion Systems (IAAPS). The outputs of Vicentiu's PhD project are also anticipated for integration as part of a new generation of engineering software tools aimed to assist engineers in the creation of mathematical models used to support further powertrain development tasks.
Data from the World Health Organisation (WHO) shows approximately 1.3 million people die annually from road crashes, which are identified as the leading cause of death for children and young adults. In the UK, there were 24,530 people killed or seriously injured in 2021 according to the estimation of the Department for Transport (DfT). Besides concerns on the road safety aspect, road traffic crashes cost most countries 3% of their gross domestic product, leading to considerable financial loss to individuals, their families, and the entire nation.
Meanwhile, various studies prove that human error was the sole factor in more than 50% of road accidents, and was a contributing factor in over 90%. Commonly seen human errors such as drowsy driving, distracted driving, and chemical impairment caused by alcohol or drugs form part of today’s road traffic system, threatening everyone’s life safety. However, the current development in autonomous driving can’t fully mitigate this issue since the takeover by a human driver is still needed before the SAE level 5 is reached, which is decades away. Propelled by societal pressure and legislation, Driver Monitoring System (DMS) was introduced by car manufacturers to tackle this long-existing problem, combining driver behaviour obtained from a camera and driving behaviour from the vehicle itself to determine the driver’s state. Despite the effectiveness of existing commercial systems, the lack of direct measurement remains a challenge to further improve the accuracy. On the other hand, the feasibility of extracting physiological information such as vital signs based on non-contact approaches in the lab environment has been proven.
Therefore, the focus of Gengqian's project is the development of a novel non-contact driver monitoring system for attentiveness detection via radar, camera, or ultrasonic sensors. Firstly, physiological information is obtained by signal processing and then compared with the ground truth from body-attached sensors to develop a robust non-contact vital sign monitoring system. On this basis, extracted features such as heart rate, respiratory rate, skin temperature, and body movements are combined with observations from real-world driving experiments and brain activity measured by EEG to develop a new model of driver attentiveness. For example, a reduction in heart rate, respiratory rate, or blink rate could be good indicators of low attentiveness.
Addressing climate change requires profound behavioural changes, including within transport. Indeed, reducing car use is one of the most impactful mitigation behaviour changes that individuals can make. Yet, travel behaviours are amongst the most difficult to change. This is partly because they are strongly habitual – unconscious routines triggered by contextual cues (e.g., ‘it’s 8am, time to drive to work’) rather than the product of conscious deliberation of alternatives (e.g., ‘which mode of transport would be best today?’). But since habits are cued by stable contexts, changes in context destabilise habits. Consistent with this, research shows that disruptions – whether concerning a person’s life-course (e.g. moving home) or physical or social context (e.g. infrastructure disruption) – provide opportunities to reshape behaviours in new directions. Interventions targeted to moments of change are thus more effective than at other times.
While much research has explored these ‘windows of opportunity’ during biographical life events, such as moving home, retiring, or becoming a parent, less is understood about how exogenously caused, structural disruptions (e.g., changes to physical environments) might disrupt habits and promote behaviour change. This PhD research will thus explore the impact that physical infrastructure disruptions (e.g., road closures) might have on modal shift and travel demand. Further, the project will evaluate the effectiveness of interventions (e.g., the provision of information, free public transport tickets) promoting active travel and public transport that are implemented during such disruptions.
Working with Transport for Wales (TfW), a series of field experiments will be conducted which evaluate the impact of behavioural measures that are introduced alongside physical changes to streets as part of TfW’s South Wales Metro project. Combined impacts of the interventions alongside the structural disruptions on travel mode change will be measured using TfW travel data as well as through the collection of both qualitative and quantitative survey data.
Hydrogen fuel cells are a vehicle power source with several advantages compared to the fossil- fueled incumbents. Fuel cells emit no harmful emissions, producing only electricity and water from hydrogen fuel and oxygen from the air. The electricity generated is used to power electric motors, similar to battery electric vehicles (BEVs), but the use of a consumable fuel instead of batteries alone negates the need for time-costly recharging. Hydrogen fuel can also be produced in a ‘green’ manner, such as by solar-powered electrolysis, which is more environmentally sustainable than fossil fuel use. This combination of benefits make hydrogen fuel cells a pivotal technology for the reduction of carbon emissions in the transport sector.
To feed the chemical reaction in the cell, oxygen is provided to the cathode from the ambient air, but must be compressed and managed in various ways to maximise performance and efficiency. Components added to the system which handle inlet air and improve fuel cell efficiency also induce parasitic losses, reducing overall system efficiency by consuming electrical energy. Air handling consumes 5% of the power provided by the stack in some examples, but could be much more, so is a key area for development to understand and improve system efficiency. There are existing methods to offset parasitic losses, such as using turbines to recover energy from the exhaust flow, as is common in turbocharged diesel engines. This appears to be less lucrative for fuel cells, as the exhaust flow is different in nature. For example, it is comparatively low temperature and is more humid, so contains less energy, and is non-pulsating, presenting different requirements and considerations. These gains and losses from air handling components must be assessed at a system level to ensure optimal air management for fuel cells. There are also further restrictions to consider regarding the practicality of air management solutions, such as avoiding contact of the exhaust water with electrical components.
The aim of Matt's PhD project is to optimise air handling systems for hydrogen fuel cells, particularly for heavy duty applications. Fuel cells are more suited to heavy duty applications than light duty due to the low volumetric density (energy per unit volume) of hydrogen. Heavy duty vehicles tend to have sufficient available space that is needed to store enough hydrogen for an appropriate range. The expected project methodology is as follows:
1. Conduct research on the interaction between the air path and the fuel cell to understand the requirements and constraints of the fuel cell’s air supply. This will help appreciate the role of air handling components later in the project. It is predicted this stage will consist of a literature review and numerical testing in GT Suite to supplement findings from secondary sources.
2. Match the air flow requirements to existing air management solutions. This will consist of further literature review to comprehensively assess a breadth of options, noting the roles, effects, pros, and cons of different components and configurations.
3. Devise an improvement to modelling techniques for fuel cell air management. This might be a humidity model which better represents real life conditions and provides data which is closer to that of physical experiments, for example.
4. Use knowledge gained to propose novel air handling systems and carry out system optimisation. This will provide an understanding of the pros and cons of different configurations and subsequently determine the best applications for each.
Jac’s research will deliver a green bond designed to finance low-carbon bus operations. This document will provide asset specifications (e.g., par value, issue price, coupon rate, and an expected credit rating), a sector/business breakdown (e.g., profitability, liquidity, solvency, legislation, and identified risks), and evidence of alignment to the ICMA green bond principles and UK taxonomy. The value added of Jac’s research will be the integration of a novel probability of default (PD) model which considers the cashflows associated with various "real options".
This topic is important because most UK bus operators cannot afford to decarbonise their fleets, especially post-Brexit due to the absence of the EIB lending facility. The UK government’s recent strategy has revolved around centralised public procurement; however, this is both insufficient and unsustainable. It follows that the market needs a green financial instrument to raise private investment for low-carbon bus operations.
Jac’s methodology will be strongly based around Moody’s credit rating methodology, and the ICMA and CBI green bond handbooks. Moreover, there will be careful consideration of legal requirements and documentation surrounding bond issuance and the bus sector.
In response to the climate emergency, transport is transitioning from Internal Combustion Engine Vehicles (ICEVs) to Electric Vehicles (EVs). Despite concerns about toxicity and resource depletion, Life Cycle Assessment (LCA) literature suggests that on average, EVs reduce whole Greenhouse Gas (GHG) emissions by up to 45%. However, EVs have a complex life cycle. The supply chain relies on a diverse range of raw materials produced upstream before manufacture, while post-manufacture, the use stage extends potentially up to 20 years before reaching its end-of-life for recycling. Hence, the environmental impacts are temporally distributed across the life cycle stages. To date, automotive LCA relies on historic data and arbitrary methods that are limited in their ability to capture how future impacts will evolve. Therefore, there is considerable uncertainty about the future consequences of the uptake of new technology such as EVs, adding risk and ambiguity to whether the automotive landscape is moving towards the sustainability agenda.
This PhD project develops prospective methodology that combines the LCA framework with Integrated Assessment Models (IAMs) to anticipate how future environmental impacts of automotive technology will evolve. IAMs consider potential socioeconomic development pathways to optimize outputs such as what future energy mix scenarios may look like. Advanced LCA techniques in Python are developed to incorporate IAMs into LCA inventories, providing the ability to explore future impacts of markets, production processes, and technology. These processes are then used to explore the long-term environmental impacts of automotive that account for changes in upstream production, temporal distribution across life-cycle stages, and potential downstream pathways for end-of-life recycling.
The UK is moving towards zero carbon emissions by 2030. To reach this objective, it is necessary to develop technologies to capture and transform CO2. Artificial photosynthesis, a carbon-negative process that mimics the reaction in plants, is capable of transforming CO2, using energy from the Sun, into different molecules such as methanol which can then be used as liquid fuel. However, poor conversion and selectivity of current artificial photosynthesis mechanisms are the main barriers to the commercialisation of the technology.
Solution: We will investigate the role of continuous microreactors, devices with channel dimensions below 1 mm, which can provide a step-change needed in the technology because of their exceptional mass transfer, offering better conversion and control in the selectivity of the process.
Most of the work to boost the process has focused on the reaction chemistry (e.g. improving the catalyst), but reactor engineering and process intensification can be parallel research lines to improve the technology. Only a few groups have reported the use of microreactors for continuous CO2 reduction and they stated that the better mass transfer in these devices enhanced the selectivity towards liquid hydrocarbons. Mass transfer is essential for reagents to move across the boundary layer adjacent to the surface of the catalyst. It is especially crucial in multi-phase reactions, such as in the case of artificial photosynthesis. Despite the promising results using continuous microreactors, the reactor role in the process has not been deeply understood and further investigation and optimisation of the channel designs could lead to a superior control in the process.
The reactors will be 3D-printed with metallic materials (copper or aluminium) in a laser melting printer at the University of Bath. 3D printing provides flexibility to try different channel designs. The internal surface of the channels will be coated with carbon nitride-based photocatalyst and irradiated with an artificial sunlight lamp. Water saturated with CO2 will be circulated through the reactor by a HPLC pump. At the end of the experiment, the products collected will be analysed with Raman Spectroscopy and Gas Chromatography (GC). The catalyst will be characterised by Scanning Electron Microscopy (SEM), Transmission Electron Microscope (TEM), X-Ray Diffraction (XRD), X-Ray Photoelectron Spectroscopy (XPS) and photoelectrochemical techniques such as transient photocurrent responses. The optimisation will also be augmented by computational studies, which aim to establish a relationship between the products obtained, the flow dynamics, and the mass transfer effects.Enquire now
Batteries based on carbon fibre reinforced plastic (CFRP) have the potential to supply power with an improved overall efficiency (vehicle power to weight rather than battery power to weight) compared to current battery technologies. By integrating batteries into the structure in the form of CFRP, lightweighting is not only achieved from the change in material but also from the removal of the non-structural dead weight of conventional batteries and their casements. For example, in automotive applications, structural batteries achieve a 26% theoretical mass saving over use of separate systems for energy storage and load carrying.
The current state-of-the-art in structural batteries is a half-cell based on a structural cathode. Significant work is required before a full cell can be manufactured and expected to sustain loading for multiple discharge and mechanical load cycles. Three projects are suggested which focus on challenges at different length scales this is project A:
Micromechanical scale - Mechanical resilience: During charging, ions are absorbed into the fibre (intercalation) which causes the anode to swell. Swelling impacts the residual stress state, mechanical properties and microstructure of the composite material, and may result in microscale fracture. Such physical changes will critically influence the ability of the material to hold charge and carry structural load. In this PhD, Paloma will focus on use of synchrotron techniques to measure fibre scale mechanical properties of both anodes and cathodes during charge cycling, accumulation of microscale damage and understanding of ion intercalation patterns within the anode. Work will progress to understand similar properties under axial fatigue loading. A proposal for synchrotron time has already been made.
Lithium-ion batteries are prevalent sources of electric energy for a variety of applications, ranging from portable electronic devices like mobile phones, tablets and laptops to Electric Vehicles and Hybrid EVs. Compared to alternative energy storage technologies, Li-ion batteries have excellent energy-to-weight ratio, no memory effect and very low self-discharge rate in idle state. These favourable properties together with the continuously decreasing production costs have established Li-ion batteries as the unique contender for automotive as well as aviation applications.
In the automotive sector, the increasing demand for EVs and HEVs is pushing manufacturers to the limits of contemporary automotive battery technology. These applications form a very challenging task since operating of EVs and HEVs demands large amounts of energy and power to ensure long range and high performance, whilst the battery cells must operate safely, reliably, and durably for a time scale of the order of a decade or more. Typically, a battery pack for an electric vehicle consists of a large number of the battery cells, physical packaging (including bus bars, casing and connectors), and Battery Management System (BMS). A BMS is composed of hardware and software controlling the charging-discharging states, guaranteeing reliable and safe operation. The BMS also handles additional operations, such as cell balancing and thermal management of the pack. The design of a sophisticated BMS is necessary to ensure long life and high performance because battery behaviour varies in time. Additionally, the BMS is crucial for safe usage because Li-ion batteries may explode or ignite if overcharged.
Fundamental physics-based mathematical models allow for highly accurate descriptions of the state of a battery cell; however, their complexity makes obtaining solutions computationally expensive (often prohibitively so). Alex's PhD is focused around using the tools of mathematical analysis to develop efficient numerical methods which by design preserve important structures of the governing model (system of differential equations) at the discrete level. Numerical methods that retain, for example, the correct level of energy dissipation across the system are crucial to accurately reflect the state of the cell. Efficient structure-preserving numerical methods could lead to the more widespread adoption of physics-based models in battery management systems and ultimately improve vehicle lifetime, performance, range, and safety.
The development of a modern powertrain system is a complex task that starts with the definition of the system level requirements. Once these requirements have been defined the physical design and manufacture of the system can begin. Today the system is then evaluated experimentally to verify that it meets all the design targets. This is a slow and laborious process, with only a limited capacity to study all the important use cases. In future, verification needs to be much faster and more robust. This PhD is focussed on the development of digital tools to speed up the process, combined with the intelligent use of experiments where these are necessary to give confidence that the system is fit for purpose.
An important focus of the research is the need for a better and faster way to verify our designs early in the development process, building on existing system modelling capability. AVL have significant expertise in the functional representation of the powertrain system in a systems modelling environment – SysML.SysML can be used to capture the capture functional, performance, and interface requirements of the powertrain as a way to evaluate system level interactions before detailed physical models of the components are available.
Lukas' research aims to use this expertise to accelerate the verification phase of the process, performing elements of the system verification in software that today are performed experimentally. Clearly not all of the system behaviours can be verified in this way, experiments will still be essential. Advanced experimental techniques developed by AVL will be used to allow a mix of physical and simulated components to be tested together in real time, bridging the gap between model based and experimental processes in a way that offers a highly robust and rapid verification process.
The methods developed during the PhD will be demonstrated by applying them to a battery electric vehicle concept – incorporating the system simulation, automated generation of test sequences and execution of these sequences on the state of the art experimental platforms with the new IAAPS research facility.
The aim of this research will be to investigate the benefits and trade-offs from the use of predictive, multi-objective control strategies for X-EV connected hybrid vehicles. Charlie will be applying significant rigour to identifying beneficial combinations of mobility system attributes and technologies to carry into more detailed problem definition, simulation and control function development culminating in the practical demonstration of one or more predictive control strategy. The project will be conducted in collaboration with IAAPS partner AVL.
As of the present, a limited but increasing number of automotive companies are bringing to market some form of look ahead, predictive functionality for powertrain management. The scope of these systems is generally somewhat limited, although broader, multi-objective approaches are beginning to emerge in research. There is, at present, an open research question around how the ideas of predictive controls, combined with the emergence of effective high bandwidth communication for vehicles , may be used to best effect in a real-world, multi-objective system.
Vehicle attributes for optimisation may include, without being restricted to: emissions, driving range and energy consumption, performance availability, system lifetime and health or financial costs. It is inevitable that the performance of a system with respect to one attribute will not be independent of others, resulting in a complex optimisation task. In addition, it is possible to assess the performance of a vehicle system over a variety of time horizons, from instantaneous through to whole-lifecycle performance. The advent of advanced connectivity in automotive and mobility as a whole will also increase the potential for impact of an individual vehicle on the wider fleet or infrastructure and vice-versa when control decisions are being made.
The battery cell is probably the most critical component of an EV, and key to the sustainability of future transportation solutions. Currently most battery testing is performed using very “clean” DC test currents whereas in reality, when used in a vehicle, the battery is subjected to current profiles with a lot of high-frequency (AC) components owing to the commutation (switching) of the inverter power electronics. Paramount in understanding how this affects its performance as part of a real powertrain system is the understanding of its electrochemical behaviour and processes.
The goal of this study is to investigate the influence that current ripple has on a Lithium-ion battery cell when it is applied on top of the DC current used to charge/discharge the cell.
Several studies have demonstrated that current ripples applied to cells can impact their performance (capacity, internal resistance, aging, etc) either positively or negatively. This PhD seeks to understand these phenomena in detail through experimentation and thermal-electro-chemical modelling of the cell behaviour, to predict the impact that any profile of current ripple might have on a particular type of battery. The research will have a strong experimental aspect to collect data from a range of battery cells, which in turn will directly support the theoretical investigations.
Howard's outcomes will inform best-practice for powertrain hardware design (inverters and filter capacitors) and software strategies implemented in the Battery Management System, as well as contribute to the understanding of how other techniques, such as battery self-heating using AC, might be applied in the future.
Ryan will develop a reduced order thermal model of a high-speed permanent magnet machine, forming a key part of a future digital twin. The model will allow for a variety of cooling methods such as air, water, and oil to be simulated. The proposed model will enable predictive and real-time estimation of the electric machine’s thermal behavior. Specifically, enabling the temperatures of physically difficult to measure components to be found, such as the rotor or magnets. By better understanding the temperature of key components within the machine in real-time and into the future the machine can be overloaded more often without damage. This will improve the power density of the machines and enable special test cycles to be performed that may otherwise have been thought to cause overheating.
Abdelrahman's PhD will address the shortcomings associated with the conventional map-based controller design and calibration practices used in powertrain development. It will provide novel, futuristic, non-linear physical causality predictive modelling and experimental approaches for system identification to conclude a real-time capable control system. The project will be undertaken in collaboration with Koenigsegg Automotive AB and Freevalve AB on the novel cam-less engine technology, Freevalve, facilitating major efficiency and power improvements for future powertrains. It will enable the full exploitation of the technical potential of a camless engine and the reduction of harmful gaseous and particulate matter emissions, putting the technology in a market-leading position ready for large-scale implementation.
The supply of low carbon energy to a rapidly growing fleet of electric vehicles (EVs) presents major network constraint and energy supply challenges. From a network perspective, peak load increases resulting from uncontrolled EV charging could surpass the capacity at vulnerable points in the power network, thus requiring expensive grid upgrades. From an energy perspective, variable renewable energy generation does not always align with EV charging demand. As such, any excess renewable energy currently requires storage or curtailment which are both expensive for suppliers.
The smart charging of EVs can help to form a synergistic relationship between the transport and energy sectors, thus accelerating their decarbonisation. Smart charging exploits EV demand-side flexibility by shifting charging time or modulating charging power, subject to grid constraints and the vehicle owner’s needs. Efficient and practical smart charging algorithms require accurate quantification of EV flexibility at different scales to maximise the whole-system benefits.
Current attempts to model and optimise EV charging tend to make large and unrealistic assumptions about consumer travel and charging behaviour. In addition, the modelling of charging at a range of locations is understudied (e.g. domestic vs commercial setting). Studying the relationships between driving behaviour, charging behaviour and the energy system, over a range of spatial and temporal scales can reveal the value of flexibility. Furthermore, understanding how changes in EV charging behaviour and flexibility affect the energy system at local and regional level is critical for energy suppliers and network operators to allow fast and cheap integration of EVs and renewables into the grid.
Isaac's PhD will investigate the definition, quantification, aggregation and optimisation of EV flexibility, and their consequential system values to appropriately reward EV drivers, based on their level of flexibility. Spatiotemporal analysis of charging behaviour will be used to model charging demand in a granular detail with realistic assumptions, identify potential vulnerabilities in the distribution network, and assess the degree of misalignment with renewable energy. To fully realise the potential financial and environmental benefits, EV charging will be optimised over a range of spatial (e.g. single EV, EV cluster, street level, town/city level, regional level and national level) and temporal scales (e.g. hour, day, week, month), and against different weather conditions and local demographics. The outcome of this research will inform how charging optimisation and behaviour should evolve with increasing renewable penetration and changing mobility patterns, and the required upgrading in charging and electrical infrastructure.
Kacper’s PhD is intended to advance the field of computational hydrogen combustion modelling in internal combustion engines (ICE), of which the main focus is the modelling of combustion in predictive scenario, in order to accelerate the development of sustainable (people, profit, planet) powertrains by brining new tools and expertise to the industry.
When employees pitch their radical business opportunities to resource holders, they are likely to use language in a way that is inconsistent with the current language around strategic priorities. This way of using language may mean that the resource holders imagine the meaning and image of the opportunity in a way that is inconsistent with what the employee intended. This miscommunication leads to inefficiencies in the evaluation and selection process of new venture projects and may lead the organization to miss on the exploration of new opportunities. The aim of this research project is to understand how this type of miscommunication is being or can be prevented through collaborative communication processes between the two parties. In addition, the development of a framework for facilitating internal conversations about radical business opportunities.
A smart and high power density charger is the key power electronics converter to overcome challenges such as range anxiety, slow charging for battery electric vehicles and plug-in hybrid electric vehicles. Wide bandgap (WBG) semiconductor devices, such as SiC and GaN, with fast switching transitions provide a solution to meet stringent automotive requirements for high power on-board chargers, while maintaining a compact size and lightweight design.
Constantinos' PhD will be investigating an innovative multi-level topology tailored for WBG devices. Multi-level topologies offer many advantages such as modularity, scalability, lower losses, limited voltage gradients, and higher AC voltage quality. The modularity of a multi-level topology also lends itself to higher fault tolerance, which is attractive in safety-critical applications. It is widely-accepted as the most promising topology for high voltage and high power applications. In automotive applications, this topology will enable the use of higher voltage DC bus systems and also help facilitate the penetration of low voltage WBG devices in these applications.
In an era where technology and transportation are so interlinked, new mobility concepts arise such as Mobility as a Service (MaaS). MaaS is expected to produce significant improvements in mobility such as the increase in the modal share of more environmentally friendly and efficient mobility options, the reduction in private car use/ownership, improving accessibility and frequency of the transportation network and the strengthening of cooperation and collaboration between public and private entities in order to reinforce the integration of transport modes in one platform accessible to everyone.
Despite being a well-known concept its implementation and subsequent effects have been not been widely explored when it comes to the connection between urban areas or even the linkage between urban and rural areas. Rita's research will be focused on those aspects of MaaS in order to assess its feasibility in these environments and making sure that the concept is design to respond to the citizen's needs while corresponding to the expectations of its implementation.
The context of Julian's research is the urgent global climate challenge of preventing a global mean surface temperature increase of more than 1.5 °C compared to the pre-industrial average. We are already 80% of the way to this threshold (Morice et al 2021, Met Office 2021). In the UK, road transport has reduced its carbon footprint less than other sectors since 1990, and larger vehicles are particularly problematic to decarbonise due to the huge infrastructure requirements for electrification, and the limited range provided by battery traction. Hydrogen fuel cells are a possible solution for powering larger road vehicles cleanly, as outlined in the Hydrogen Strategy of the UK Government (2021). However, about 95% of hydrogen is currently produced by steam methane reforming, which has significant carbon emissions even when carbon capture is implemented (Howarth and Jacobson 2021). Most research on the environmental impacts of hydrogen production, storage and delivery has focused on a narrow subset of hydrogen technologies or a narrow range of environmental indicators. There is also a need to consider the intersections between decisions made for road transport and competing uses of hydrogen for ammonia production and industrial processes, and domestic heating and cooking. This project is intended to fill these gaps and to assess the potential of hydrogen technologies to sustainably decarbonise large road vehicles. The methodologies will encompass:
Julian's research project will produce as its outputs: a review of recent LCAs of hydrogen; a review of the most promising hydrogen technologies; a detailed consequential LCA of hydrogen production, storage and delivery (cradle to station); and an online decision support tool that shows costs and benefits (financial and environmental) for a range of hydrogen pathways under user-selected economic and technological scenarios.
The citizens jury being co-organised by the University of Bath (UoB) and the local Council (BANES) in late 2021 will address sustainable travel from the city to the University and surrounding area. It seeks to promote collaboration between the University and local stakeholders to identify acceptable technological and behavioural options for safe, sustainable, cost-effective, and healthy travel by staff, students, and residents in the local area. The proposed PhD research will build on this deliberative activity by developing and evaluating one or more modal shift and/or reduced demand behaviour change interventions to achieve BANES’ and the University’s goals (including UoB’s Climate Action Framework and the Council’s sustainable communities agenda).
Jesse's project will draw on current work being undertaken within the AAPS Transportation & Society theme on consumer decision-making in relation to low-carbon transport, including timing modal shift interventions to ‘moments of change’ (periods of disruption or transition, such as the start of the academic year, when new students have not yet developed travel habits). It will also seek to incorporate engineering innovations in AAPS, for example exploring how digital technologies and sustainable vehicle/fuel technologies may form part of the final intervention packages, along with social/behavioural elements.
This project will harness new topology electrode nanomaterials developed in our laboratory, for applications in fuel cells used in transportation. Their unique nanostructures give enhanced reactivity and stability compared with nanoparticles currently used. The technology is “platform agnostic” in terms of fuel, with properties and reactions common to a range of fuel cells. This project will explore their use in fuel cell reactions and devices, bridging the gap from preliminary data to real world applications and commercialisation.
Electric Vehicles are key to reducing carbon emissions. While rechargeable batteries are likely to be the main technology for cars, there are long-distance applications (boats, planes, lorries, trains) for which the energy density by weight of batteries is too low, and alternatives are required. Fuel cells overcome this problem. In a fuel cell, electricity is generated by an electrochemical reaction between a fuel and oxygen. Powering vehicles in this way uses 50% less fuel than a combustion engine, and the energy density of typical fuels is tens of times greater than that of lithium ion batteries, whether by weight or volume. [1,2] However, wider commercialisation of fuel cells is currently limited by catalyst performance, cost and stability.
Our team has recently developed a route to new nanostructure topologies for high performance electrodes in fuel cells. The process is green, mild, and industrially scalable, and can be used to grow a range of different metals. The electrodes comprise 3D nanowire networks, which give ultra-high surface areas; high stability, avoiding the use of nanoparticles, which present a major limitation on current device lifetimes; and high reactivity. The technology has been adopted widely, and superior reactivity and stability have been demonstrated in the oxidation of alcohols, glycerol  and formic acid .
Our electrode materials are “platform agnostic” in terms of fuel. There are potential advantages and disadvantages to each of hydrogen, alcohol, and formic acid, and future adoption depends on advances in green methods of production – respectively through water electrolysis, biofuel, and CO2 reduction. Underpinning all of these fuel cell types is the counterpart oxygen reduction reaction, for which superior activity and stability have also been reported for electrode materials similar to ours. Whichever technology wins out, our materials can therefore play a part.
This project will extend the previous work in three directions:
The development of a hydrogen economy is a key part of the UK’s commitment to net zero as recommended by the Climate Change Committee. Whereas battery electric vehicles are expected to satisfy the vast majority of light duty vehicle applications, their limited energy density means that they are unsuitable for many energy-dense applications such as long-distance haulage, shipping, rail and aviation. Equally, long charging times significantly affect their suitability for high availability applications.
Fuel cells overcome these issues by separating the energy storage from the energy conversion, enabling refuelling times similar to those of conventionally fuelled vehicles (<5 minutes) while maintaining zero emissions at the point of use. However, durability is key challenge for fuel cells in these markets where the system lifetime target is 25,000 hours (by 2030) and 1 million miles for Class 8 truck applications according to the US DoE.
Aaron's research aims to tackle this challenge by producing predictive models of the causes of PEM fuel cell degradation, seeking to understand not just individual degradation modes, but the interactions between them and their development over the lifetime of the stack. Current techniques are usually split into theoretical and empirical models. Whereas theoretical models are predictive; for electro-chemical devices they tend to be highly complex, slow to simulate and contain many parameters which are difficult to determine. Conversely, empirical models are fast running, but tend to be highly simplistic have low generality. The aim of this project will be to bridge this gap to enable investigation into how design and control strategy changes will affect the long-term fuel cell durability.
In addition to the main project aim, several secondary objectives are proposed. These will form a series of interim milestones for the project and include development of standardised test procedures, accelerated aging methods, condition monitoring techniques, requirement specification for future cell development and recommendations for control strategy targets.
Turbochargers are increasingly used to improve engine performance and power output, while downsizing. They will be key in helping to reduce fuel consumption and emissions through increasing engine efficiency. For next generation technology, turbocharger speeds and pressure ratios will increase, causing blow-by to increase and potentially drastic oil leakages/insufficient lubrication due to inadequate sealing. Incorporating novel sealing technology has the potential to increase turbocharger operating ranges, maximise efficiency and improve reliability. One approach is to use non-contacting mechanical face seals, which employ a very thin fluid film between a rotating face (rotor) and a stationary face (stator) to maintain a clearance. This allows operation at much smaller clearances increasing efficiency, reducing wear and having an improved dynamic response.
This project focuses on investigating the dynamics and suitability of a non-contacting mechanical face seals for operation in high performance turbocharger applications. A mathematical model will be developed for this fluid-structure-interaction problem, based on thin film flow (lubricating approximation) and a spring-mass-damper model for the faces. Key factors to incorporate include thermal effects, high speed operation and the effect of external disturbances due to components surrounding the seal interacting with it. A robust numerical technique will be formulated that is computationally efficient and produces sufficiently accurate results. A numerical study will allow safe operating conditions to be identified, and which factors play a significant role in potential destabilising behaviour. The outcomes of this work will inform designers of seals efficiency and reliability under different geometric and operating conditions.Enquire now
The ever-growing global presence of the electric vehicle is seen as a positive solution to decarbonise the transport industry. As a result, chemists and material scientists are aiming to develop materials that can be used as a backbone for improved electrodes and electrolytes for next-generation batteries and supercapacitors.
Dan's research will focus on the generation of materials that are considered to be part of the next generation of batteries through the use of non-line-of-sight deposition techniques, including chemical vapour deposition (CVD) and atomic layer deposition (ALD). This will provide opportunities to produce current collectors and thin films that are well-defined. Through the methods chosen, the microstructure, morphology and chemistry of the composites can be finely-tuned to overcome potential challenges that battery materials face, such as volume changes during charging and the mechanical, chemical or electrochemical degradation of the electrodes.
Focus will be drawn to potential lithium- or sodium-chalcogenide intercalation or conversion type electrode, or electrolyte materials, such as Lithium sulfides, lithium phosphates and lithium anti-perovskites, and their sodium counterparts.
The initial stages will involve the synthesis of molecules that can be used as precursor material for CVD and ALD, which will then be characterised via a host of methods, including X-ray diffraction, NMR and elemental analysis. The thermal decomposition will be assessed, as will the ability of the precursor to create a thin film. The thin films will be characterised using scanning electron microscopy and will be assessed on its ability as a charge carrier.
The advantages of the chosen techniques (CVD and ALD) will be exploited to improve upon cell performance. These include the ability to deposit uniform layers on a surface which can be used as a protection against chemical degradation, the ability to deposit conformally active materials onto structured backbones, such as nano-tubes, -flakes or -rods. There is also the advantage of high levels of control over stoichiometry of new materials that will be tailored to suit the cell performance by appropriately choosing the precursor materials, changing the deposition parameters and through chemical doping.
Thin ceramic films are hard to manufacture, but very important in energy conversion. Electrospraying (ES) is a versatile technique which has been used to dry, crystallize, and fabricate ultrathin layers of various materials. In ES, a high voltage is applied to a liquid precursor flowing through a nozzle, to create an aerosol of charged monodispersed nanodroplets. Drying air is fed into the drying chamber vaporising the droplets and forming solid particles with crystalline structures. ES allows (i) control over the degree of atomization of the feed, thus increasing the droplet surface area and extent of drying, (ii) control of the direction of the aerosolization jet and particle size deposition; (iii) ultrathin layer formation, controlled by the throughput of the aerosolization jet and voltage; and (iv) film self-healing behaviour when exposed to moisture.
In this project, we will exploit ES to manufacture ultrathin electrolyte and electrode layers for used in solid oxide fuel cells (SOFCs). SOFCs exhibit greater energy efficiency and can tolerate a far wider range of fuel materials compared to PEM. For this reason, they are increasingly being proposed as aviation and marine propulsion devices using zero carbon fuels such as ammonia. SOFCs are presently limited in performance by the ion conductivity of the solid electrolyte, and this would be much improved if a thinner electrolyte could be created. They are also challenging to manufacture due to sequential processing including multiple thermal steps.
Here, we will assess the benefits of electro-confined particle deposition at the fundamental level, as well as explore how the ES process affects the overall performance of SOFCs. At the University of Bath, we have demonstrated the capabilities of ES for polymorph control, and crystal formation in organic molecules; therefore, building on this established framework, this interdisciplinary PhD project - containing aspects of Chemical Engineering, Chemistry and Manufacturing - will further develop this technique to provide insights into the effects of electrical charges and confinement on the formation of ultrathin ceramic layers. We envision, that this PhD project will encompass the following activities:
Nanoporous materials used in adsorption applications play an important role in hydrogen purification and the storage and processing of low carbon fuels. However, numbering in the 100,000s, the enormous range of existing and hypothetical materials to be considered for a specific application makes standard, experimental and simulated screenings prohibitively expensive. Machine learning is emerging in materials screening but often the focus is on traditional machine-learning prediction, where a model is first trained using a very large number of simulations of the application of interest and then used to estimate properties of interest for all structures in the data set to identify the top performing new materials.
We have developed a new approach combining Bayesian optimisation/ active machine learning and molecular simulation, which allows us to identify the top performing materials of a database without having to calculate the performance of 100,000s of individual structures. One of the core attractions of this new methodology is that our model can make recommendations based on limited information, updating itself in-situ from molecular simulation of performance for a given application. We have successfully applied this approach to simple performance targets such as the uptake of hydrogen at a particular storage pressure or the separation of two simple gases. While impressive, this type of screening does not include important process parameters including the presence of impurities or kinetic separation effects which might mean that in practice a promising material identified through computational screening might not be as promising as thought. Another area that is beyond the scope of current screening approaches due to the computational effort required is optimising process conditions such as temperature or pressure ranges.
In this PhD project you will combine active machine learning techniques/Bayesian optimisation with molecular and process simulations to extend our screening approach to more realistic conditions for applications in the areas of hydrogen purification and low carbon fuels, the exact nature of which will be determined in discussions with an industrial partner. As our approach allows identifying promising materials out of a database of 100,000s materials by just conducting a few 100s – 1000s simulations, screening using more expensive simulations such as process simulations becomes more tractable. The overall aim of the PhD project is to integrate multi-scale modelling from the molecular scale to the process scale into the screening of porous materials for processing low carbon fuels, and to develop methods that combine the type of cheap molecular simulation that we already conduct with more complex, targeted simulations (or even experiments) to identify promising porous materials. This will include developing algorithms capable of choosing which simulations / experiments to run in order to discover the best material with the least effort. The project is suitable for engineers and scientists who are interested in modelling and machine learning and have good maths skills.Enquire now
This research will focus on understanding the link between battery degradation and methods of battery thermal management, especially with respect to cells of different sizes.
Exposure to high temperatures and temperature cycling are two of the most significant aggravating factors for battery aging. The trend in automotive applications is for ever increasing cell sizes, with some vehicles now featuring cells of several hundred amp-hours and up to 1m long. As cells sizes increase achieving a uniform temperature across and through the cell is increasingly difficult because only the cell surface is cooled, and because the cooling fluid (air/water/oil) will typically reach some parts of the cell before others. This non-uniform temperature distribution will very likely lead to non-uniform aging of the cells, which this PhD aims to investigate, quantify, understand, and propose mitigation mechanisms against. This is an important topic not only for maximising the lifetime of the cells in the vehicle, but also when considering the potential value of the cells in second life, or how they might be recycled.
Work will focus initially on immersive cooling, where battery cells are directly immersed in a dielectric oil. This is because immersive cooling is considered the most advanced and high-performance approach to thermal management and is a current focus for research. Problems with this include the cost and weight added to the system by the fluid. This trade-off will be examined by considering the possibility of partially filling the battery with fluid so that cells are only partially submerged, reducing fluid weight at the expense of some thermal homogeneity.
Opportunities may exist for synergy with the group working on Structural Batteries, depending on the size scale of the batteries which that group have succeeded in producing by this time. These opportunities will be explored as appropriate, as the relevance of this proposed doctoral research is particularly relevant to structural batteries owing to their increased value and added difficulty in recycling them. The work of the existing group to date has focussed primarily on producing working batteries. Degradation has not yet been investigated, and whilst recyclability has been embedded in materials selection no analysis has been performed in this space.
Electrochemical testing of cells will be possible with charging/discharging experiments and electrochemical impedance monitoring. Microstructural characterisation of the impact of degradation will form a key aspect of the doctoral study. This will involve the use of nanoindentation, electron and atomic force microscopy and/or Focused Ion Beam (FIB) to study internal changes to the microstructure through the preparation of microscale cross-sections and lamella. Synchrotron work (microtomography, X-ray diffraction, and/or spectroscopy) with in-situ electrochemical testing will reveal regions of heating/degradation, formation of stresses locally at anode or cathode, and opportunities for retaining battery performance. These insights will be used to generate enhanced models of degradation, providing crucial insights into predicted lifetimes and potential recycling opportunities associated with these systems at end of life.
Green molecular or di-hydrogen (H2) is an exciting and interesting option as a low-carbon fuel for road transport, including light- and heavy-duty vehicles, with the added benefit of lower negative air quality impacts compared with fossil fuels whether used in ICEs or fuel cells.
However, a major challenge with on-board storage is refuelling of fixed tanks which requires a distributed, publicly accessible infrastructure incorporating the safe management of high-pressures (up to 70 MPa for compressed gas) or low temperatures (below 30 K for liquid H2). An alternative option is a modular approach where empty tanks are replaced with tanks that have been filled separately by well-controlled and ultra-safe agents.
This transfers refuelling risks (and skills) to these agents from the public and does not necessarily require extensive infrastructure. Refuelling (or “retanking”) may also be quicker than currently envisaged at a H2 station. However, there are issues that need to be understood to determine whether this modular approach is technically feasible, economically viable, would be acceptable to the public and would lead to lower carbon emissions over the vehicle life cycle compared with all the major options including batteries.
Will's PhD would identify and assess these issues lading to the conceptual design of a prototype modular refuelling system (or systems) for the road vehicle fleet. An important outcome will be CAD and possibly also physical desk-top models to demonstrate the principles and operation of these systems.
As the automotive industry continues to de-carbonise, Fuel Cell vehicles provide a promising alternative to conventional ICE vehicles. Charaterising a fuel cell virtually is fundamental in unlocking performance and efficiency gains in its operation and development. Using data and specifications from the manufacturer to develop a theoretical model is often time consuming given the number of prarmeters and the level of fidelity desired in each use case. Therefore the aim of this work is to paramterise and develop fuel cell models and then to validate using experimental data gathered using efficient experimental methodology.
Depending on the use case, a variety of model types can be used which in turn will utilise varying structure/method to characterise the fuel cell. Definition of the parameters to valdate the model will be chosen and finally upon choice of use case, a methodology and can be selected to produce data in which to validate the developed model.
Alex's work will look into fuel cell model development and parameterisation process along with the expereimental methodology to validate such a model. The experimental procedure will be streamlined based on chosen parameterisation techniques.
The objective is to design a stator winding reconfiguration system which is commercially and technically attractive. The concept of reconfiguring the stator windings depending on the motor operating point is widely known to offer performance advantages in terms of motor efficiency and torque density for a given mass of rare earth magnets. From work carried out in the summer project it is also shown that there is potential to reduce the specification of power electronics.
Reconfiguration of windings between star and delta modes of operation is a common practice in industrial applications for start-up of induction machines, however commercial implementation of such systems for traction applications is almost non-existent owing to cost and packaging constraints. The objective is to develop and demonstrate such a system which could be commercially relevant in automotive traction motor applications, and to evaluate its efficacy.
The concept which will be developed within this project is based around a mechanical switching mechanism, as we believe this offers the only realistic route to achieve the cost requirement and make this technology commercially relevant for mainstream automotive applications. Previous work details semiconductor-based switching systems but are difficult to realise for under 200€ for the power electronics alone, not considering control circuitry or cooling. In contrast, the mechanical switching solution uses abundantly available materials and inexpensive manufacturing techniques and so has excellent potential for cost optimisation. To realise the full benefits of this concept, it is desired to be integrated into the motor packaging. This will ensure that the total package is optimised for volume and mass and is preferable to integration within the inverter because it avoids the need for 12 cables connecting the motor and inverter. Despite multiple patents in this area no commercial product has yet reached the market, highlighting the difficulty of achieving a practical solution. We believe one of the key factors in producing a practical design is reducing the number of switches, or more precisely the number of electrical contact faces, since these are ultimately what limits the package volume. A key area in which the proposed solution progresses the state-of-the-art is in reducing the number of electrical contact faces by making maximum use of double-throw switches. A full review of possible switching mechanisms will be conducted as part of the work, including electrical schematics and actuation mechanisms, with a view to minimising cost and volume. This work will ultimately analyse such systems with the aim of establishing a design methodology which can be applied to the general case, to analytically trade off volume with performance, ensuring the project outputs are widely applicable.
The internal combustion engine (ICE) has been the ‘silver bullet’ in powering machinery for the transportation, mining and construction industries. However, with existing and upcoming regulations on CO2 emissions, the industry is exploring the viability of fuelling ICEs with hydrogen as a carbon neutral alternative – notable examples include BMW, Toyota, Yamaha (now also rotary ICEs) and JCB.
Current hydrogen combustion research focuses on achieving high brake thermal efficiency (≥45%) while keeping NOx emissions levels low by utilising direct injection fuelling strategies. This results in increased volumetric efficiency and allows for a more precise control of abnormal combustion events compared to port fuel injection. Nevertheless, topics such as combustion irregularities, turbocharger design for hydrogen-specific operation, heat transfer and injection strategy optimisation remain underresearched.
Current structural batteries research, as part of ongoing AAPS/GKN PhD projects, has identified that current state of the art carbon fibre structural battery architectures need to be revised as using a layered approach places too much physical distance between anode and cathode which slows ion transfer and reduces battery performance. To overcome this issue two novel architectures are being considered. One seeks to intermingle anodes and cathodes (based on carbon fibres coated with battery materials) by decomposing tows of carbon fibres into thinner layers (tens of fibres thick) and the second looks to create ultrathin layers of electrospun batteries to act as veils in manufacture of non-crimp fabrics. Each requires a combined mechanical and chemical manufacturing process to be established together with prototype/proof of principle manufacturing systems. The full PhD will look to prototype the manufacturing process and use a combination of electrochemical and mechanical tests to demonstrate a working product.Enquire now
The advent of new technologies has driven rapid change and evolution in the field of spatial navigation and wayfinding. Travelling and driving to a location has become easier thanks to GPS systems and the emergence of autonomous driving. However, it remains unclear how these changes can affect drivers’ cognitive abilities and spatial knowledge acquisition, and in turn their performance as well as their safety. For example, there is recent evidence that the use of visual GPS can negatively affect attention and driving performance in users (Hejtmánek et al., 2018; Seminati et al., 2022). We have recently shown by developing an immersive virtual reality driving game that audio-visual GPS may counteract the negative effect of visual only and auditory only GPS systems and improve drivers’ performance (Seminati et al., 2022). Also, we have shown, as others before us, that different types of navigational aids can have a different impact on the users due to individual differences in spatial abilities and preferences (Baldwin 2009; Seminati et al., 2022).
Different factors have been related to the impact of GPS systems on spatial acquisition and one important aspect that previous research has highlighted is that passively following instructions decreases the level of involvement in the environment, thus affecting spatial acquisition and later driving performance (Parush, 2007). “Passive mode” also characterises autonomous driving, where individuals are passive passengers. A recent study has shown that self-driving vehicles are likely to produce a degradation in spatial survey knowledge (i.e., in the ability to create a map-like perspective of the environment), in people who drive frequently and do not usually ride as passengers (Qin & Karimi, 2020). In contrast, we have some initial evidence that autonomous driving can have similar effects to multisensory GPS systems in terms of drivers’ performance and behaviour (Seminati et al., 2022). Hence, further driving-simulation studies are needed to understand the possible impact of autonomous driving and multisensory GPS systems on spatial acquisition and drivers’ behaviour.
Laura's PhD project aims to build on our first study by developing and testing different types of multisensory GPS systems while accounting for user’s spatial abilities and wayfinding preferences. Laura's project aims to assess differences between navigating with the support of GPS systems and moving in the same environment through an autonomous driving mode, while assessing users’ performances under different levels of cognitive load in a virtual reality driving environment. This project will inform the development of effective and user-tailored multisensory GPS and autonomous systems and add to our understanding of spatial cognition and representation in everyday driving.
The promotion and application of electric vehicles (EVs) is a vital strategy for many countries to achieve reduced carbon emissions and realise carbon neutrality by 2050 (Global EV Outlook 2021). As the power source of electric automotive, power batteries play a decisive role in the performance, driving range and lifespan of EVs. At present, lithium-ion (Li-ion) batteries are the most promising candidate to propel usage of EVs due to their high energy/power density, long cycle life, high stability and high energy efficiency. However, Li-ion batteries are sensitive to the operating temperatures. For instance, at temperatures > 35oC, side reactions inside the batteries are intensified, causing capacity fading and battery ageing. More seriously, thermal runaway incidents of EVs due to overheating of batteries are frequently reported, raising questions and attention in EVs’ safety. On the other hand, when the temperature is low, typically < 15oC, the discharge capacity is largely reduced due to the increased internal resistance and depressed reaction kinetics, leading to a much shorter driving range. In addition, the non-uniform temperature distribution will cause inconsistent electrochemical process and further reduce the battery pack capacity and cycle life. Therefore, an efficient battery thermal management system is essential to ensure the safety and performance of Li-ion batteries in EVs.
The main aim of this research is to design high-performing and safer Li-ion battery designs by using numerical modelling that can fully characterise the interactions between chemical reaction and thermal transport mechanisms of current and next-generation battery designs. The numerical models will be used to provide insights into thermal propagation, possible overpressure due to runaway chemical reaction and other associated risks in the enclosed systems. In addition, we will use the validated models to predict performances of new battery configurations and propose adequate safety measures to prevent disasters, with reduced physical testing. Such an approach is imperative for the design of safer and high capacity Li-ion batteries for EVs.
To achieve our aims, we proposed the following specific objectives:
The future of private car use in towns and cities needs a rethink to respond to multiple and interdependent drivers of change including (in the UK): climate change legislation, rising cost of living and health inequalities. These effects, in combination with new technologies to support hybrid working and on-demand mobility, could be leveraged to exert a downward pressure on the incumbent system of private car ownership.
However, research into the psychology of car dependency shows that travel habits are hard to change and that, even when people state a desire to drive less - for example because of environmental concerns - they find it hard to change their behaviour. Many people are, or feel they are, locked-in to system of a car ownership through a complex range of social, economic and built environment/structural factors.
This aim of Sarah's PhD is to view the system of car dependency through a local, national and international lens to investigate the social, economic and built environment factors that influence car ownership amongst two age cohorts – “Millennials” and “Gen Z” – with a particular focus on gender differences. The insights from the initial research will be used to generate and test a range of scenarios for future car use, ownership and travel demand.
The hypothesis is that Millennials (now age 27-45) have become locked-in to car the system of car ownership (due to societal norms) but that Gen Z’s (now age 13-26) values, attitudes and behaviours towards driving make them more likely to choose not to own a car in the future. The results of researching the hypothesis will be used to develop and test scenarios where young people are supported to move away from individual car ownership. These scenarios could be used by politicians and community groups to design future local and national transport policies aimed at reducing car ownership. The scenarios will help to highlight the positive system change which could build local resilience and sustainability (e.g. to meet the 2030 Sustainable Development Goals). Methodology:
• Literature review focused on car use, ownership, system lock-in across different segments to identify underpinning theories and gaps in research knowledge;
• Statistical analysis of national data sets (NTS, Census, Household Survey etc) and also international longitudinal data e.g. German Socio-Economic panel to develop insights into attitudes and behaviours towards ownership (past/current and future projections);
• Qualitiative data collection through deliverative processes and focus groups targeting 16-26 age group (e.g. students/apprentices/new graduates to develop future scenarios.
• A final stage may be design of a laboratory experiment to test and validate scenarios;
The future scenarios could be used to make (top-down) policy recommendations for local/national governments as well as (bottom-up) community action to support young adults to choose not to own a car
Transportation is in transition, with new technologies such as electric vehicles, fuel cells, and hydrogen. But, for example with battery electric vehicles, the case for their environmental benefits rests on a bet -- that the negative impacts associated with producing the vehicles are outweighed by the benefits of reduced future impacts when the vehicles are driven. The negative impacts are relatively certain since they are happening now or in the near future. On the other hand, there is much greater uncertainty about the future benefits, since they are expected over the coming decade(s). Given the long time-scales involved, how should engineers be making decisions now about what technologies to develop and deploy?
One approach to answering this question is to use Life Cycle Assessment (LCA), but in its basic form this is based on historic data, which can be a poor representation of the future. An improved answer comes through the application of "Prospective LCA", which deals with the fact that, for example, the impacts of end-of-life recycling of batteries may be different in 20 years' time than it would be if it happened today, due to increased renewable energy supply in the future. But this still assumes that the vehicle will be used as intended over its lifetime, and successfully recycled in the expected way. This greater uncertainty in future benefits and impacts is not currently modelled in LCA of vehicles, making it difficult to know how much trust to place in the results during the design and decision-making process.
In this project you will build on current cutting-edge prospective LCA to improve the treatment of future uncertainty within these models, and apply this to design choices within future vehicles. Engagement with an industrial partner would allow the value of different ways of assessing and presenting future uncertainty to be evaluated, and linked to specific engineering decisions. You will gain experience of the theory of industrial ecology and life cycle assessment, and uncertainty and sensitivity analysis, set against the wider context of sustainable transport and the future of battery electric vehicles in particular. Practically, you will work with tools such as Python and Brightway2 to implement LCA calculations, Monte Carlo uncertainty simulations, and sensitivity analysis.
New hydrogen storage technology is required to improve volumetric and gravimetric storage density. The USDoE has set an ultimate target of 6.5 wt.% and 50 kgH2/m3 gravimetric and volumetric storage densities respectively.1 At present, only chemical hydrogen storage methods can approach this storage capacity under non-severe conditions: for example, dibenzyl toluene, an organic hydrogen carrier, has a storage capacity of 57 kgH2/m3 when fully hydrogenated. In comparison, pure hydrogen must be either stored at 700 bar or cryogenic condensed liquids which are highly energy consuming.
Liquid organic hydrogen carriers (LOHCs) bring a tremendous advantage in that they can be stored at low pressure and ambient temperature, much like conventional hydrocarbon fuels.2 Their drawbacks relate to chemical stability, the energy efficiency through multiple hydrogen storage and release cycles (they must be regenerated off-board), and the use of precious metals in the catalytic conversion. It is these challenges that this project will aim to address.
LOHC systems cycle between a H2 rich state, storing H2 through catalytic hydrogenation, and a H2 lean state releasing H2 via catalytic dehydrogenation. An ideal LOHC would be inherently safe to transport using fossil fuel infrastructure (low viscosity), have low cost and a highly reversible hydrogenation/dehydrogenation. 1st generation LOHCs such as benzene and toluene are petrochemically derived, and their potential was recently realised by establishing a 4,000 km H2 supply chain between Brunei and Japan. 2nd generation LOHCs are based around alcohol and amine mixtures which can be coupled using an appropriate catalyst to release molecular H2 and are sustainably derived from biomass. In this project, you will assess a range of existing and proposed technologies in terms of their potential energy integration into on board propulsion systems directly or as H2 transport vectors to re-fuelling stations. Based on the outcomes of this study you will then drive the development of a prototype delivery/transport system to efficiently store hydrogen at one location in a safe to handle LOHC and release at another location or into a PEM fuel cell at from this H2-rich LOHC to generate electricity.
The project will involve technological assessment of current and emerging technologies, the development and assessment of catalyst materials and integration into a small scale device.
The research is divided into three work packages to address these challenges:
1) Analysis of existing and proposed technologies as part of automotive propulsion systems from and energy integration approach.
2) Development of catalytic technologies to reduce the amounts of precious metals required to cycle these LOHC molecules between H2 rich and lean states.
3) Development of a prototype H2 delivery system.Enquire now
The next generation of aero-engines will be net-zero and compatible with synthetic fuel and hydrogen. This creates a unique problem for the engine designer, as the dimensions of the core architecture will be radically reduced. The resulting reduction in the height of the compressor blades leads to the requirement to control blade tip clearances to significantly tighter tolerances. The blade tip clearance is controlled by the radial growth of the compressor discs, which is strongly affected by the temperature distribution and in turn the heat transfer in rotating cavities. The aircraft operating conditions change for take-off, cruise and landing, and so the prediction of both steady-state and transient heat transfer and disc temperatures is vital if these engines are to operate with future fuels. The aim of this project is therefore to make experimental heat transfer measurements using the Compressor Cavity Rig at the University of Bath, and to use the data generated to validate theoretical models, which in turn will be used in the engine design process.
The direct impact of the work will be to create new thermo-mechanical models at Rolls-Royce. These practical design codes will predict the behaviour of new engine architectures over a range flight cycles, including aborted landing. The models require both empirical data from experiments and information from more theoretical flow physics and fundamental heat transfer. Essential to the success of the impact from the project is the close collaboration between the academic team and engineers at the company. This link is well established and facilitated through the in-kind support offered by Rolls-Royce.
There is a strong academic link to the University of Surrey Rolls-Royce University Technology Centre (UTC) for Thermo-Fluid Systems, which includes world-leading expertise in high fidelity Computational Fluid Dynamics (CFD). This takes place through quarterly review meetings and workshops with the Surrey UTC and Rolls-Royce teams in the UK, USA and Germany. There is also a strong link to the University of Oxford Department of Atmospheric Physics, who explore similar rotating phenomena at a different scale relevant to weather systems. Within Bath we collaborate with the Department of Mathematical Sciences on machine learning and statistical modelling to explore new data methods and analysis, which are also of key interest to Rolls-Royce. This project therefore offers a multidisciplinary opportunity to bring new insight into the design of next generation aircraft.