Welcome to the EPC’s Enterprise Collaboration Toolkit â formerly known as the Crucible Project. Here you will find EPCâs landmark project supporting university and industry collaboration in engineering by showcasing and sharing the keys to success.
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The Enterprise Collaboration Toolkit was inspired by the EPCâs landmark 2020 Annual Congress, Industry & Academia: Supercharging the Crucible, which highlighted five areas of mutual interest.
This toolkit includes case studies from a wide range of HE institutions and industry partners, focusing on these 5 themes which can all can be accessed via the links below:
Academics at all levels â whether early career staff looking for opportunities to establish a network or senior leaders who want to extend the role of industry partnerships in their strategy or who want to improve graduate employment outcomes.
Managers in industry looking to establish links with academics to boost research, development, innovation and talent pipeline.
Policy-makers and sector agencies with an interest in industry and academia working more closely for the benefit of the economy, society and regions.
Advisors and contributors
In 2021 the EPC called for case study contributions to build this toolkit to help our members forge stronger industry links by sharing experiences and developing resources. We were delighted to receive nearly 50 applications to contribute case studies, exploring one or more of the Crucible Projects five main themes. These submissions were reviewed in detail by the EPC’s Research, Innovation and Knowledge Transfer Committee (RIKT) and 25 were shortlisted to present at our very successful Crucible Project online launch event on the 16th February 2022. With over 100 attendees joining us throughout the full-day event we saw presentations of a fantastic range of the case studies now available in this toolkit. We would like to extend our greatest thanks to the RIKT committee for all their enthusiasm and hard work on this project, in addition to all those who presented at the event and/or contributed case studies to make this an extensive, and what we hope will be a very useful, resource.
More to come
This is just the beginning of the Crucible Project toolkit â this will be a living and growing resource to provide best practice examples of academic-industry partnerships to help you find research funding, place graduates in employment, create work-based learning and many other collaborations. To ensure the continuous growth of this resource, members will soon be able to contribute their own, or further case studies.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Abstract: Driving the Electric Revolution is led by Newcastle and is a collaborative R&D project to build supply chains in Power Electronics Machines and Drives. The University led the bid and as we amass supply chain capability we will generate ÂŁ Billions in GVA.
Newcastle University has been embedded in the academic and industrial development of the North East of England since 1834. Recently, one of its core competencies, Machines and Drives research, has been used to attract investment to the region from Industry and Government helping to increase the economic prospects for the North East region.
Newcastle University is the national lead organisation for Driving the Electric Revolution Industrialisation Centres an Industrial Strategy Challenge Fund Wave 3 competition. The centres serve two purposes,
A focal point for development of manufacturing processes in Power Electronics, Machines and Drives (PEMD) through investment in cutting edge manufacturing equipment.
The training of researchers, students, employees of industrial partners on these important new processes.
The Driving the Electric Revolution (DER) Industrialisation Centres (DERIC) project aims to accelerate UK industrialisation of innovative and differentiated PEMD manufacturing and supply chain solutions. They are doing this by creating a national network to coordinate and leverage the capabilities of 35 Research and Technology Organisations (RTO) and academic establishments, based within four main centres. Supported by 166 industrial partners it represents the largest coordinated industrialisation programme the UK PEMD sector has ever seen.
Newcastle University has, in living memory, always been at the forefront of Electric Machines and Drives innovation globally. It was inevitable that Newcastle would lead the DER project given its pedigree, reputation and the fact that it was supported by several companies in several sectors, Automotive, Aerospace and domestic products who undertake product research in the North East and who seek to manufacture in the UK if possible.
Newcastle did recognise however that it couldnât deliver the government programme alone. There were four institutions which formed a consortium to bid into the competition, Newcastle University, University of Strathclyde, Warwick Manufacturing Group and the Compound Semiconductor Applications Catapult in Newport South Wales. Over time they have been joined by University of Nottingham, University of Birmingham, Swansea University and University of Warwick. Letters of support were received from 166 Industry partners, 27 FE and HE organisations expressed support as did 13 RTOs. Although the national bid was led by Newcastle, it took a more North East regional view in development of its delivery model.
Therefore, in addition to this national work, Newcastle extended their DERIC application beyond Newcastle to Sunderland where they worked with Sunderland council to establish a DERIC research facility in the area. Sunderland city council worked with Newcastle to acquire, fit out and commission the lab which received equipment from the project and is due to open in 2022.
Nationally the primary outcome is the establishment of the Driving the Electric Revolution Industrialisation Centres and the network.
The four DERIC act as focal points for the promotion of UK PEMD capabilities. They design develop and co-sponsor activities at international events. They send industrial representatives to meet with clients and research partners from UK, Europe and Asia, as well as developing a new UK event to attract leading PEMD organisations from around the globe.
In Newcastle the universityâs sponsorship of both the national project as well as the DERIC in the North East is helping attract, retain and develop local innovation and investment. The equipment granted by the DER Challenge to the centre includes a Drives assembly line as well as an advanced Machines line. The DERIC is focused primarily in the development of manufacturing processes using the granted equipment. The equipment was selected specifically with these new processes in mind. The success of the DERIC program already means that the country and the region have attracted substantial inward investment.
Investments by three companies came to the North East because of the capability developed in the region. They have all agreed partnerships with the university in the process of establishing, acquiring and investing in the North East. The three companies are:
British Volt mission is to accelerate the electrification of society. They make battery cells. Their Gigaplant in Northumberland will be the second Gigaplant in the UK. They are investing ÂŁ1Bn into the region creating around 5,000 jobs both at the plant and in the supply chain.
Envision also make batteries. Unlike British volt the Envision cell is a Gel pack. Envision has the first Gigaplant in the UK at Sunderland. They are investing a further ÂŁ450M to expand the plant in Sunderland and potentially another ÂŁ1.8Bn by 2030.
Turntide Technologies invested ÂŁ110M into the region acquiring three businesses. These have all in some fashion been supported by and supportive of the PEMD capability at Newcastle over the past six decades.
The university has worked tirelessly to help create an ecosystem in the region for decarbonisation and electrification.
The last stage of this specific activity is the creation of the trained employees for this new North East future. The university, collaborating across the country with DER partners, is embarking on an ambitious plan to help educate, train and upskill the engineers, scientists and operators to support these developments. It is doing this by collaborating, for the North East requirement, with the other universities and further education colleges in the region. Industry is getting involved by delivering a demand signal for its requirements. The education, training and up skilling of thousands of people over the next few years will require substantial investments by both the educators in the region as well as industry.
As the pace of electrification of common internally combusted applications accelerates the need for innovation in the three main components of electrification, power source, drive and machine will grow substantially. The country needs more electrification expertise. The North East region has many of the basic building blocks for a successful future in electrification. Newcastle University and its Academic and Industrial partners have shown the way ahead by collaborating, leading to substantial inward investment which will inevitably lead to greater economic prosperity for the region. Further information is available from the Driving the Electric Revolution Industrialisation Centres website. In addition, there are annual reports and many events hosted, sponsored or attended by the centres.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Dr Grazia Todeschini (Kingâs College London) and Kah Leong-Koo (National Grid UK)
Keywords: Electrical Engineering, Power Systems, Renewable Energy, Computer Model
Abstract: This case study deals with a collaboration between KCL and National Grid on a EPSRC project. The project deals with assessing the impact of renewable energy sources on the electricity grid. This assessment will be carried out by using a transmission grid model provided by National Grid and device models developed by KCL.
Topic of the case study
This case study deals with the development of advanced models to study the impact of renewable energy sources, and more in general, inverter-based devices, on the UK transmission grid. More specifically, this project focuses on the impacts in terms of voltage and current distortion. This topic is referred to as âpower qualityâ in the specialist literature.
Aims
This research was motivated by various reports presented in the technical literature in the last decade, where a general increase of harmonic levels has been observed. A similar trend has been reported in several countries, simultaneously to the installation of increasing levels of renewable energy sources and other inverter-based devices. These reports have created some concerns about harmonic management in the future, when more renewable energy sources will be in services. Ultimately, the project aims at forecasting harmonic levels in 2050, and at determining impact on the equipment, and possible mitigating solutions.
Collaborating parties
This case study involved the collaboration between the Department of engineering at Kingâs College London and National Grid UK.
Project set up
Power quality is a specialist area within power systems that deals with deviation of voltage and current waveforms from the nominal values, in terms of both amplitude and frequency. The academic PI worked for a few years in the power industry, with the aim of specialising in power quality and understanding the issues faced by the power industry, as well as the tools that are used to carry out power system studies. The industrial PI is an expert in the area of power quality and has been involved with many standardisation groups as well as professional organisation to help developing common tools to harmonise the approach to power quality. Therefore, the two PIs have a similar expertise and background that allowed them to discuss and define common areas of research. When looking to develop such a specialist project, it is very important that all parties involved have a common ground, so that it is possible to interact and work in the same direction.
Outcomes
The project is still not finished, however, some of the original objectives have been achieved:
A 2050 scenario has been developed, by using: transmission system model data provided by National Grid, device models developed through research and testing, and identification of future locations of renewable energy sources. Although the case is still under development, preliminary results indicate that harmonic levels are expected to increase, but they can be managed using existing design practice.
A distribution system model with harmonic injection has been developed and it is currently under discussion with the industrial partner. This model is needed by the industrial partner to be able to represent the presence of renewable energy sources on the power grid at lower voltage levels.
This was the first collaboration between the academic and the industrial PI, and was very positive and constructive for both parties. Therefore, the two collaborators now planning to continue this collaboration via other projects in the future.
Lessons learned, reflections, recommendations
In terms of technical developments, the collaboration has been very productive, as it allowed the exchange of information between industry and academia. Specifically, the industrial partner provided data and models that are used by power system engineer working at National Grid to carry out renewable integration studies. This information cannot be found in the literature as it is protected by NDAs. On the other side, the university provided expertise in developing models that can be used to represent specialist equipment, and that are needed to study the integration of renewable energy sources. Development of such models is time consuming, and the support of the university allowed faster development and testing.
COVID impacted the collaboration because, as part of the original project plan, placements in industry were to be carried out. However, ultimately they didnât take place. The industrial placements would have helped the model development to proceed faster as it would have allowed closer communication. The use of remote meetings mitigated the impact of COVID and still allowed the project to be carried out successfully. For any project of this type, it is very important to be able to work closely with the industrial partner and being able to meet regularly. Being in the same office allows to discuss more frequently, rather than waiting for formal meetings to be set.
For a technical project aiming at analysis a very-well defined problem, one recommendation is to find the technical experts within the company that can provide expertise. This may take some time in the initial stages, but at the end it will pay off as it will allow to carry out meaningful technical discussions.
Further resources
We published two papers and others are in preparation:
Z. Deng, G. Todeschini and K.L. Koo: âModelling Renewable Energy Sources for Harmonic Assessments in DIgSILENT PowerFactory: Comparison of Different Approachesâ, 11th International Conference on Simulation and Modeling Methodologies, Technologies and Applications.
Z. Deng, G. Todeschini and K.L. Koo: âComparison between Ideal and Frequency-dependent Norton Equivalent Model of Inverter-Based Resources for Harmonic Studiesâ, 2021 IEEE Innovative Smart Grid Technologies Conference Asia.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Abstract: The theme of the session is about how industry currently searches for academic expertise for applied research and other interventions. A speaker from the school of engineering and one from their partnership platform will talk about the importance of online searches and having effective academic profiles for web searches, discovery and engagement. The speakers will be: Kendra Gerlach (Director of Marketing and Communications at the Virginia Commonwealth Universityâs College of Engineering) and Justin Shaw (UK Development Director for ExpertFile). The university will identify specific industry engagements through their outreach via their own strategic focus and using the content development, structured data for discovery and broad reach distribution channels provided as part of their partnership with ExpertFile.
The following case study addresses, when it comes to knowledge exchange, that there is a fundamental issue in the abilities of industry to identify and source relevant academic experts and applied research centres in the first place.
The aim of the strategy covered in this case study is to determine if improved discovery via online channels and making use of relevant content has more positive outcomes for industry access and engagement with academia. We will discuss how industry searches for academic expertise for applied research, consulting and other interventionsâ and how the efforts of the Virginia Commonwealth University (VCU) College of Engineering improved the attraction, interest and engagement from industry and beyond.
VCU College of Engineering needs a strategy for academic expertise discovery
As a young and growing institution, VCU College of Engineering was aware that its faculty had much to offer for knowledge exchange but were almost impossible to find by potential external partners. Before adopting a strategy and partnering with the global online expert platform, ExpertFile, the College had no solution for an online academic directory that offered more than just contact and basic biographical details. A few academics already had websites for their own labs, some had up-to-date information, some included curriculum vitae. The presentation was variable and unattuned to external perspectives. Many werenât even cited on the Collegeâs website domain, and most were invisible to an online search.
The College recognised that there was a need to make their academics more easily findable with professional-looking content that would surface on top search engines, while also having the expertise promoted beyond the Collegeâs website itself.
The old strategy failed to deliver
Before the College implemented a strategy focused on improved discovery and on delivering relevant and engaging content, it used traditional and digital marketing tactics that didnât have really an anchor of information for the academic experts. Faculty relied on their own personal connections to industry and other researchers. As the College grew, it became evident that to form research partnerships and pursue large grants, faculty must be more easily found and their expertise easily accessed for academics and non-academics alike.
Putting the strategy into action
When the College pursued the strategy to increase expert visibility, many senior academics were resistant and did not want to change â as they did not fully understand the value to them and their work. The College proceeded with the adoption of professional online profiling knowing that if the strategy did not succeed, at the very least they would have current strengthened content for their showcasing academics online.
The College chose a technology platform to mobilise their strategy and modernise their market visibility – to be competitive in the engineering space. They chose to work with ExpertFile as it supported their own web presence and offered updated multimedia content formats such as videos, images and books. Beyond technology, ExpertFileâs content distribution channels (with partner promotional channels and expert-seekers) also increased content visibility beyond their own website.
With the resistance of faculty a concern, and the need for faculty to provide content for the profiles, the team adopted an initial message related to the student recruitment priority in order to get them on board (academics understood the need to be seen by potential students).
Faculty members were given their own dedicated page on the egr.vcu.edu domain. This was essential to success. Each profile has a unique, personalised url on the website so that search engines can easily find them, resulting in higher search ranking. With 93% of online sessions starting with a search engine[1], 91% of pages getting no organic search traffic from Google [2] and 75% of internet users never scroll past the first page [3] this was critical for âdiscoveryâ.
The unique urls also facilitated the Marketing and Communications Department to employ cross-linking, a key part to the success of the strategy. The marketing team promotes links to profiles in all content related to an academic. Every news story, award or newsletter mention includes a link. Social media uses links to drive viewers back to the website and the profile. The team have also encouraged the parent University to include links to faculty profiles whenever that person is mentioned.
VCU Engineering created a directory of profiles for the entire College members plus subdirectories for each sub-uni and department for ease of discovery. For example, a searchable subdirectory of only Computer Science faculty or Mechanical Engineering faculty which routes to that departmentâs homepage.
Profiles arenât limited to biographical information and publications; they include areas of expertise, industry experience, research patents, videos, books, media and event appearances â all valued by industry and others. This content is as important as the initial discovery as it offers searchers a greater understanding of the academic expertise and its value to them.
Engaging industry benefits reputation Industry partnerships and opportunities are an important focus of the College and academics knew that improved discovery would have widespread benefits; improving the reputation of the College and its faculty and attracting other groups – prospective graduate students, foundations, academic colleagues, associations and media.
Faculty members with strong reputations in their fields often advance in their own academic associations. For instance, one of the Collegeâs Computer Science experts has been named president-elect of a global organisation. A nuclear engineering professor is now Director General of the World Nuclear Association. Without discovery, academics and colleges rely on their limited connections and miss these larger opportunities.
News media seeking experts struggle to find credible sources. A VCU associate professor that specialises in aerosols is now regularly featured in media and on television because he is now easily findable as an expert in this field. Media coverage has a direct lead generation impact for industry engagement and secures trust in the credibility of the source.
Many of the Collegeâs academics have now established industry partnerships, and the marketing team knows that these efforts have contributed to those successes. From the formation of pharmaceutical clusters locally to the fastest licensing agreement done by the University, the commitment of this strategy to support those successes has paid off.
Measuring impact and results
The College uses tools like Google Analytics Studio to measure results and track progress. Since it has employed trackable pages and cross-links to the content, it has been able to record the steady progress of these efforts. Faculty have benefited from much-elevated search rankings including top-ranked faculty profiles which are viewed between 2,000 and 3,000 times a year, with more than 2,000 different visitors viewing each profile. In a given year, the College now tracks over 90,000 unique visitors that have viewed their academic profiles.
More than 70% of the views come from organic search, which means when a faculty memberâs name is searched, their profile pages are among the top results, and in some cases are the number one search result.
The strategy continues to add value
Kendra Gerlach, Director of Marketing and Communications at VCU College of Engineering, and co-author of this case study reflected:
âResearchers often assess their involvement and benefit from supporting ventures on a three year cycle. If the second year is better than the first, and if the College is seeing success, they continue a third year.â
Kendra is happy to report that the College is now in year five of using ExpertFile and this expert profiling and searchability strategy.
Key Takeaways:
Creating profile pages that live on the Collegeâs own website domain is critical. Give academics a unique url that can impact search rankings.
Deliberately linking to profiles from other sources: marketing materials, other organizations, social media, helps to elevate search rankings making faculty easily discovered by industry and others.
Moving beyond academic credentials and publications to a broader array of expert content appeals to industry, making academics more approachable.
Overcome technology limitations with platforms that integrate with current systems. If current profiles are inadequate, enhance them or use knowledge exchange focused content that can be easily discovered and acted upon.
Access summary presentation slides of this case study as a pdf document here.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Dr Gareth Thomson (Aston University, Birmingham), Dr Jakub Sacharkzuk (Aston University, Birmingham) and Paul Gretton (Aston University, Birmingham)
Abstract: This paper describes the work done within the Mechanical, Biomedical and Design Engineering group at Aston University to develop an Industry Club with the aim to enhance and strategically organise industry involvement in the taught programmes within the department. A subscription based model has been developed to allow the hiring of a part-time associate to manage the relationship with industry, academic and student partners and explore ways to develop provision. This paper describes the approach and some of the activities and outcomes achieved by the initiative.
Introduction
Industry is a key stakeholder in the education of engineers and the involvement of commercial engineering in taught programmes is seen as important within degrees but may not always be particularly optimised or strategically implemented.
Nonetheless, awareness of industry trends and professional practice is seen as vital to add currency and authenticity to the learning experience [1,2]. This industry involvement can take various forms including direct involvement with students in the classroom or in a more advisory role such as industrial advisory or steering boards [3] designed to support the teaching team in their development of the curriculum.
Direct input into the curriculum from industry normally involves engagement in dissertations, final year âcapstoneâ project exercises [4], visits [5], guest lectures [6,7], internships [8,9] or design projects [10,11]. These are very commonly linked to design type modules [12,13] or projects where the applied nature of the subject makes industrial engagement easier and are more commonly centred toward later years when students are perceived to have accrued the underpinning skills and intellectual maturity needed to cope with the challenges posed.
These approaches can however be ad hoc and piecemeal. Industry contacts used to directly support teaching are often tied into specific personal relationships through previous research or consultancy or through roles such as the staff involved also being careers or placement tutors. This means that there is often a lack of strategic thinking or sharing of contacts to give a joined up approach â an academic with research in fluid dynamics may not have an easy way to access industrial support or guidance if allocated a manufacturing based module to teach.
This lack of integration often gives rise to fractured and unconnected industrial involvement (Figure 1) with lack of overall visibility of the extent of industrial involvement in a group and lack of clarity on where gaps exist or opportunities present themselves.
Figure 1 : Industry involvement in degrees is often not as joined up as might be hoped.
As part of professional body accreditation it is also generally expected that Industrial Advisory Boards are set-up and meet regularly to help steer curriculum planning. Day to day pressures however often mean that these do not necessarily operate as effectively as they could and changes or suggestions proposed by these can be slow to implement.
Industry Club
To try to consolidate and develop engagement with industry a number of institutions have developed Industry Clubs [14,15] as a way of structuring and strategically developing industrial engagement in industry.
For companies, such a scheme offers a low risk, low cost involvement with the University, access to students to undertake projects and can also help to raise awareness in the students minds of companies and sectors which may not have the profile of the wider jobs market beyond the big players in the automotive, aerospace or energy sectors. At Aston University industry clubs have been running for several years in Mechanical Engineering, Chemical Engineering and Computer Science.
The focus in this report is the setting up and development of the industry club in the Mechanical, Biomedical and Design Engineering (MBDE) department.
Recruitment of companies was via consolidation of existing contacts from within the MBDE department and engagement with the wider range of potential partners through the Universityâs âResearch and Knowledge Exchangeâ unit.
The industry focus within the club has been on securing SME partners. This is a sector which has been found to be very responsive. Feedback from these partners has indicated that often getting access to University is seen as ânot for themâ but when an easy route in is offered, it becomes a viable proposition. By definition SMEs do not have the visibility of multi-nationals and so they can struggle to attract good graduates so the ability to raise brand awareness is seen as positive. From the perspective of academics, the very flat and localised management structure also makes for a responsive partner able to make decisions relatively quickly. Longer term this opens up options to explore more expansive relationships such as KTPs or other research projects and also sets up a network of different but compatible companies able to share knowledge among themselves.
Within MBDE the industry club initially focussed on placing industrially linked projects for final year dissertation students. This was considered relatively âlow hanging fruitâ with a simple proposition for companies, academics and students.
The companies get the opportunity to access the physical and student resource of the university
The students get a more contextualised and live project offering added practical and commercial concerns of a commercial project thereby enhancing their experience and employability
The academics are able to enhance the curriculum and build industrial contacts who can support both teaching and research going forward.
While this proposal is straightforward it is not entirely without difficulty with matching of academics to projects, expectation management and practical logistics of diary mapping between partners all needing attention.
To support this, an Industry Club Associate was recruited to help manage the initiative, funding for this being drawn from industry partner subscriptions and underwritten by the department.
This has allowed the Industry Club to move beyond its initial basis of final year projects to have a much wider remit to oversee much of the involvement of industry in both the teaching programmes directly and in their advising and steering of the curriculum.
Figure 2 shows schematically the role and activities of the industry club within the group.
Impact Beyond Projects
The use of the Industry Club to co-ordinate and bolster other industry activity within the department has gone beyond final year projects. These can be seen in Figure 2.
The Industrial Advisory Board has now become linked to the Industry Club and so with partners now involved in the wider activities of the club involvement is now not exclusively limited to twice yearly meeting but is an active ongoing partnership using the projects, other learning and teaching activity and a LinkedIn group to create a more dynamic and responsive consultation body. A subset of the IAB is now also made up entirely of recent alumni to act as a bridge between the students and practising industry to help spot immediate gaps and opportunities to support students in this important transition.
Figure 2 : Industry Club set-up and Activity
The club has also developed a range of other industrially linked activities in support of teaching and learning.
While industrial involvement is relatively easy to embed in project or design type modules this is not so easy in traditional underpinning engineering science type activity.
To address the lack of industrial content in traditional engineering science modules a pilot interactive online case studies be developed to help show how fundamental engineering science can be applied in authentic industrial problems. A small team consisting of an academic, the industry club associate and an industrialist was assembled.
This team developed an online pump selection tool which combined interactive masterclasses and activities, introduced and explained by the industrialist to show how the classic classroom theory could be used and adapted in real world scenarios (Figure 3). This has been well-received by students, added authenticity to the curriculum and raised awareness in student minds of the perhaps unfashionable but important and rewarding water services sector.
Figure 3 : Online Interactive Activity developed as part of industry club activity
Further interactions developed by the Industry Club, and part of its remit to embed industrial links at all stages of the degree, include the involvement of an Industrial Partner on a major wind turbine design, build and test project engaged in as group exercises by all students in year one. Here the industrialist, a wind energy professional, contextualises work while his role is augmented by a recent alumni member of the Industrial board who is currently working as a graduate engineer on offshore wind and who completed the same module as the students four years or so previously.
Conclusion
While the development of the Industry Club and its associated activity can not be considered a panacea, it has significantly developed the level of industry involvement within programmes. More crucially it moves away from an opaque and piecemeal approach to industry engagement and offers a more transparent framework and structure on which to hang industry involvement to support academics and industry in developing and maximising the competencies of graduates.
References
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University of Canterbury, (2021), Collaborate â College of Engineering
Aston University (2021), Computer Science Industry Club Brochure
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Dr Corrina Cory (University of Exeter), Nick Russill (University of Exeter and Managing Director TerraDat UK Ltd.) and Prof Steve Senior (University of Exeter and Business Development Director at Signbox Ltd.)
Keywords: Gold Standard Project Based Learning, EntreComp, 21st Century Skills, Entrepreneur in Residence, Collaboration
Abstract: We have recently updated our engineering programmes at the University of Exeter (E21 – Engineering the Future) with a USP of Entrepreneurship at the core of the first two years to prepare students for research led learning and the future of jobs. We have worked closely with our Royal Society Entrepreneurs in Residence (EiR) to ensure authenticity in our âreal-worldâ Gold Standard Project Based Learning (GSPBL) activities. We would like to share this great collaboration experience with our EPC colleagues.
Introduction
We have recently updated our engineering programmes at The University of Exeter (E21 – Engineering the Future). The Unique Selling Point (USP) of Entrepreneurship is embedded through Stage 1 and 2 using a new methodology combining Gold Standard Project Based Learning (GSPBL)[1] [image: Picture_1.jpg]) and EntreComp[2] ([image: Picture_2.png], the European Entrepreneurship Competence Framework).[3-5]
Gold Standard PBL – Seven Essential Project Design Elements [4]. Creative Commons License. Reference [1] – pblworks.org (2019). Gold Standard PBL: Essential Project Design Elements. [online] Available at: www.pblworks.org/what-is-pbl/gold-standard-project-design (Accessed 16 February 2022).
The EntreComp wheel: 3 competence areas and 15 competences [5].Creative Commons License. Reference [2] – McCallum, E., Weicht, R., McMullan, L., Price, A. (2018). EntreComp into Action: get inspired, make it happen, M. Bacigalupo & W. OâKeeffe Eds., EUR 29105 EN, Publications Office of the European Union, Luxembourg, pg.13, pg. 15 & pg. 20.
The 21st Century Skills developed in the early stages of the programmes prepare students for research-led learning in later stages and future graduate employment.
The Royal Society Entrepreneur in Residence (EiR) scheme, aims to increase the knowledge and awareness of cutting-edge industrial science, research and innovation in UK universities. The scheme enables highly experienced industrial scientists and entrepreneurs to spend one day a week at a university developing a bespoke project.
In this context, the EiR scheme has grown âconfidence in, and understanding of business and entrepreneurship among staff and studentsâ and we have collaborated with our EiRs to ensure authenticity in our âreal-worldâ project-based learning activities.[6] They have inspired students to pursue their own ideas and bring them to reality in ways that bring sustained regional and global benefit.
Aims
Develop collaborative relationships with EiRs.
Implement our newly developed methodology combining GSBPL and EntreComp to thread a USP of Entrepreneurship throughout our updated engineering programmes.
Integrate the experience of our EiRs via Entrepreneurship modules in experiential project launches, interactive workshops and attendance at pitch presentations.
Update assessments to include multi-media, entrepreneurial submissions including storyboards, video pitches, wireframes and websites to assess digital competency, creativity, business, collaboration and inclusivity for successful future graduate employment.
Plan
The Engineering Department worked with venture capitalist Alumni, Adam Boyden to create a MEng in Engineering & Entrepreneurship. The education team seized the opportunity during curriculum development to make the Stage 1 and 2 Entrepreneurship modules common to all engineering programmes to embed a USP of Entrepreneurship in E21.
Both our EiRs are natural educators and thrive on sharing their rich experiences and stories to mentor others through their entrepreneurship journeys.
They provide on-site technology demonstrations, prizes for 21st Century Skills and interactive workshops on entrepreneurship. This integration of EiRs into teaching and learning adds variety, and through the power of story, the students engage to a high level. Furthermore, their curiosity prompts them to construct and ask challenging questions.
The open-ended GSPBL driving questions allow groups to develop unique ideas. Most of the projects yielded excellent and highly original themes, some of which could have real value in the future should they be further developed. Â
We have observed learning opportunities for inclusivity, listening, improvements in self-confidence and more free-thinking and ideation as a direct result of our methodology combining GSPBL and EntreComp.
Using this method and mapping competences using EntreComp should improve outcomes for graduates who gain the top employability skills required by 2025 e.g., critical thinking and analysis, problem-solving, self-management, active learning, resilience, stress tolerance and flexibility.[7] Students develop an appreciation and understanding of business start-ups, ideation and successful implementation of innovative research and development through their experiential learning.
Outcomes
Our EiRs have provided insights into what it takes to be an entrepreneur and have introduced energy, enthusiasm, creativity and innovative thought processes throughout both Entrepreneurship modules.
Nick Russillâs specific contributions include team building, planning, branding, entrepreneurial skills, innovation, business development, co-hosting project launch seminars, innovation workshops, project-based learning support sessions and mock investment pitch panels.
Steve Seniorâs lectures Q&As and workshops include the beauty of failure, advanced Computer Aided Design (CAD)/Computer Aided Manufacturing (CAM), marketing and e-commerce. He mentors student teams on how to capitalise on limited resources during growth and explains risk analysis with case studies from his own companies.
The digital materials created for our blended updated programmes will remain a longer-term legacy of their involvement and provide resources available to be called on in future to sustain the impact of EiRs at Exeter.
Nick has commented that âmy time as EiR with the Exeter engineering students has convinced me that GSPBL takes education to another level, and I wish it were more widespread in education curricula ⊠The close association of learning with real-life applications and case studies has proved that students retain far more technical and theoretical information than they may do from more traditional methodsâ.
Students are surveyed at the start of Entrepreneurship 1 and the end of Entrepreneurship 2 in terms of their self-assessed ability to evidence aspects of EntreComp on their CV. Previous publications have illustrated an increase in competence over the 2 years of Entrepreneurship and we will continue to collect this data to evidence outcomes.[5]
Entrepreneurs in residence share their real-world experience and then stick around to build relationships with the staff, researchers and students. They become an integral part of the team. Student Feedback definitely proves that we’re helping to ignite sparks for a new generation of entrepreneurs. Student feedback includes:
âGain skills in areas concerning self-motivation and creativityâ⊠âbecome comfortable with risk and uncertainty ⊠a really good learning experienceâ âŠâdeveloping confidence and being able to trust yourself and take the initiativeâ… âgood innovation and technical skillsâ ⊠âlearning by doing is the only way for entrepreneurship and this course has given us a great environment and support to learn, fail, pivot and learn againâ.
Staff and students have commented on the value of injecting ad hoc real-life anecdotes of problem-solving stories and learnings from experienced entrepreneurs which is unique, valuable and significantly enriches learning experiences.
Lessons and Future Work
An individual reflective work package report is submitted by all students at the completion of two years of entrepreneurship modules. This provides a period of reflection for students and a chance to showcase their journey including valuable learning through failure, personal contributions to the groupâs success and professional development in terms of 21st Century Skills as defined by EnreComp.
Following panel Q&A at the EPC Crucible Project, future refinement includes reviewing possible additions to the reflective report and illustrating links between engineering competence and EntreComp to clearly signpost students to the relevance of Entrepreneurial 21st Century Skills for graduate employment, chartership and intrapreneurship.Â
European Commission, Joint Research Centre, Price, A., McCallum, E., McMullan, L., et al. (2018) EntreComp into action : get inspired, make it happen. Publications Office. https://data.europa.eu/doi/10.2760/574864, pp.13, 15 & 20.
Cory, C., Carroll, S. and Sucala, V., 2019. Embedding project-based learning and entrepreneurship in engineering education. In: New Approaches to Engineering Higher Education in Practice. Engineering Professorsâ Council (EPC) and Institution of Engineering and Technology (IET) joint conference.
Cory, C., Sucala, V. and Carroll, S., 2019. The development of a Gold Standard Project Based Learning (GSPBL) engineering curriculum to improve Entrepreneurial Competence for success in the 4th industrial revolution. In: Complexity is the new Normality.. Proceedings of the 47th SEFI Annual Conference, pp.280-291.
Cory, C. and Cory, A., 2021. Blended Gold Standard Project Based Learning (GSPBL) and the development of 21st Century Skills – an agile teaching style for future online delivery. In: Teaching in a Time of Change. AMPS Proceedings Series 23.1., pp.207-217.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Amer Gaffar (Manchester Metropolitan University); Dr Ian Madley (Manchester Metropolitan University); Prof Bamidele Adebisi (Manchester Metropolitan University).
Keywords: Decarbonisation; Local Energy; Skills; Economic Growth.
Abstract: Greater Manchester (GM) has committed to carbon neutrality by 2038. There is a 97m tonnes carbon emission gap between solutions currently available and a net zero budget. To bridge this innovation gap under the leadership of the Greater Manchester Combined Authority the agency brings together: Bruntwood, Hitachi, MMU, UoM, GM Growth Company, SSE and UoS to support R&D and innovation initiatives focused on customer pull to enable rapid deployment of new and emerging technologies, services and business models to meet the challenge of GM becoming a carbon neutral city-region by 2038, drive skills development and deliver economic growth.
The need for an Energy Innovation Agency
The Mayor for Greater Manchester Combined Authority (GMCA) has committed the city region to carbon neutrality by 2038. An analysis of the implications of the Paris Climate Change Agreement for Greater Manchester (GM) (Figure 1) has identified that there is a 97m tonnes carbon emission gap between solutions currently available and the actions needed to reach net zero. We refer to this as the Innovation Gap.
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To bridge the GM innovation gap under the leadership of GMCA the agency brings together: Bruntwood, Hitachi, Manchester Metropolitan University, University of Manchester, SSE and University of Salford to support R&D and innovation initiatives focused on customer pull to enable rapid deployment of new and emerging technologies, services and business models (energy innovations) to meet the challenge of GM becoming a carbon neutral city-region by 2038, driving skills development and delivering economic growth.
Forming the Energy Innovation Agency
GMCA initially approached the cityâs three universities to seek advice on how their academic expertise could be harnessed to help bridge the innovation gap. This quickly led to discussions between each of the universities that identified a wide pool of complementary, and largely non-competitive, areas of research expertise that could address the gap (Figure 2).   Â
Figure 2 Research expertise by university partner – darker colour indicates a greater depth of expertise in the area.
It was also clear that the timescales needed to deliver city wide change would not fit within a traditional academic approach to research and knowledge transfer that required a public-private partnership.
At the core of this partnership approach are three key components.
Public sector influence and leadership across both city region and local authority levels that enables new ways of working to be demonstrated and quickly built into local plans, can influence national policy and regulation, and convene wider public involvement.
The business community, end-users and investors, in its widest sense, who have the need for change and can drive change by steering the development of the business and finance models that allow rapid large-scale adoption and deployment of innovation.
Academic sector able to drive the underpinning research, access to research and test facilities to validate novel innovations, TRL and IP, and develop the skilled workforce needed.
Using existing networks, a core team comprising GMCA, Bruntwood, Hitachi, MMU, UoM, SSE and UoS came together to develop the business plan for the agency and to jointly provide the funding for the first three-years of the operation of the agency.
Vision, Aims and Objectives
To accelerate the energy transition towards a carbon-neutral economy by bridging the energy innovation gap, increasing the deployment of innovative energy solutions in GM and beyond, to speed-up the reduction of carbon emissions.
Aims:
Innovation Exploitation: supporting and scaling the most promising decarbonised energy innovations to maximise the early adoption of effective carbon-neutral energy systems.
Decarbonisation: reducing Greater Manchesterâs carbon emissions from energy to meet our ambitious target to be a carbon-neutral city region by 2038
Rapid Commercialisation: rapid transition of carbon-neutral energy innovations to full-scale integration.
Investment: creating and promoting investment opportunities for carbon-neutral energy innovations and projects in the city region.
Objectives:
Position Greater Manchester as a global destination of choice for those looking to create and deploy innovative net-zero energy solutions.
Create a clear entry point, managed development, and validation pathway, for innovators to test, trial, and scale their most promising energy technologies and services in Greater Manchester.
Enhance the connection between industry and academia âpushâ and customer âpullâ, by putting innovative products, services, and projects in front of purchasers at the very earliest stage for advice and steer.
Provide a dedicated vehicle to bid for competitive funding and for industry to generate investment value, pooling the very best innovations to solve key decarbonisation challenges.
Link local investment to innovative products and projects, to enable rapid development and deployment where clear business cases are set out.
Direct alignment to local and national policy and strategy, ensuring project delivery intelligently informs policy and vice-versa.
Foster public confidence in new approaches and technologies, creating local skills and employment opportunities and improving access to cheaper, cleaner energy for all.
Scope
With a population of 2.8 million covering 1,277 km2 the ten metropolitan boroughs of GMCA comprises the second most populous urban area in the UK, outside of London. The scope and potential for the Energy Innovation Agency is huge.
Figure 3 GMCA Energy Transition Region showing local authority boundaries.
Establishing the GM-city region area as an Energy Transition Region will provide the opportunity to develop the scale of deployment necessary to go beyond small-scale demonstration projects and develop the supply chains that can be replicated as a blue-print elsewhere in urban environments across the UK and internationally.
Progress to date
Following the investment by the founding partners a management team has been established within GMCAâs subsidiary âThe Growth Companyâ. An independent board chaired by Peter Emery CEO ENWL has also been established.
The formal launch event will take place on 28th April 2022, at which a first challenge to the innovation community to bring forward solutions to decarbonise non-domestic buildings will be set.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Author: Prof Balbir Barn (Middlesex University), Prof Tony Clark (Aston University), Vinay Kulkarni (TCS) and Dr Souvik Barat (TCS)
Keywords: Digital Twin, Model Driven Engineering, Inclusive Innovation
Abstract: Researchers at Middlesex University initiated a collaboration in 2011 with Tata Consultancy Services Research in India based on their research on lightweight methods for enterprise modelling. Since 2014, that initial introduction has developed into a sustained and ongoing collaborative research programme in programming languages and environments to support model based decision making in complex and uncertain scenarios. The research programme has supported annual sabbatical visits to the TCS research labs in India; a PhD studentship; and regular workshop/advanced tutorials at international conferences. The continuing programme is an example of industry based research problems driving academic collaboration in an international context that has led to over 30 research outputs, an Impact Case Study submitted to REF2021, a TCS software product and the establishment of the London Digital Twin Research Centre at Middlesex.
Introduction
This case study describes the outcomes of an ongoing collaboration between Middlesex University with Tata Consultancy Services Research, Indiaâs premier software research centre. The collaboration initiated in 2011, was triggered by a research paper published by Clark, Barn and Oussena [3]. The research proposed a precise, lightweight framework for Enterprise Architecture that views an organization as an engine that executes in terms of hierarchically decomposed communicating components. Following a visit to the TCS Research Labs (TRDDC) in Pune, India, a joint research programme between TCS and Middlesex was established to further the notion of the âModel Driven Organisationâ. A key feature of the collaboration was the notion of inclusive innovation, from problem location to shared mutual benefits. The research programme has supported annual sabbatical visits to the TCS research labs in India; a PhD studentship; and regular workshops/advanced tutorials at international conferences. The continuing programme is an example of industry-based research problems driving academic collaboration in an international context that has led to over 30 research outputs, an Impact Case Study submitted to REF2021, a TCS software product and the establishment of the London Digital Twin Research Centre at Middlesex.
Systemising a model for collaboration
In 2011, developing strong, sustained and inclusive model of collaboration with industry was seen as an important element of reputation building activities for Middlesex University as it set out to establish an overseas campus in India. The goal was that Middlesex should be seen to delivering impact both to project outcomes but also as value to the geographical setting of the collaboration. Â Thus, in 2011, two senior academics, Prof. Balbir Barn and Prof Tony Clark embarked on a visit to Indiaâs leading IT research centres including the Tata Research and Development Centre (TRDDC), IBM Research, Microsoft Research, Accenture Research, HCL Research, Infosys, Cognizant and others. At these visits, the senior academics were able to showcase Middlesex Computer Science research activities leading to two memorandums of cooperation with Accenture and TRDDC. Middlesex CS had also decided to establish a strong presence at Indiaâs premier Software Engineering conference(ISEC) through research papers, tutorials, and the organising of workshops aimed at capacity building of Indian academia (Value in the process).
Further meetings with chief scientist â Vinay Kulkarni from TRDDC in 2012 at ISEC, led to the idea of collaboration around the notion of the âModel Driven Organisationâ where an enterprise can be represented symbolically by a model that draws its information/data from range of software artefacts used by the enterprise in its daily operations. Executives are then able to use this model representation as a decision-making aid.
The collaboration was seen as a shared vision that would be beneficial to both partners (TRDDC and MDX) so at the outset, we agreed to make our joint research publicly available with both partners retaining the option to productise any research outputs. However, there was This collaboration can also be seen as a model for Inclusive Innovation in that the research roadmap references a problem from the âwildâ, where key stakeholders are engaged equally from research problem formulation, through to research publications and where there are mutual benefits.
The collaboration also developed a way of working that was critical to its subsequent success. TRDDC supported travel and subsistence of Barn and Clark to its research labs in Pune on annual two week âmini-sabbaticalsâ. These visits which have run since 2012 to now (only coming to pause due to COVID-19) are linked to the ISEC conference where papers, tutorials and workshops have been regularly presented. There has been a strong focus on development of young academics in India at this conference, further establishing the impact of our inclusive innovation approach by generating value in the setting. While the primary interaction is with the TRDDC Software Engineering Laboratory, seminars and other research exploration opportunities are made possible by meetings with other laboratories (such as Psychology). Some of the annual meetings have been supplemented by further meetings at Middlesex. Each annual visit is an intensive research meeting from which emerges the research plan for the year alongside a publication and impact plan. Very early on, we recognised the potential for an impact case study for the periodic research evaluation exercise conducted in the UK.
Figure 1: Research Roadmap
Outcomes
The collaboration has proved to be singularly successful in delivering concrete outcomes. Our regularly updated research roadmap (see Figure 1.) has evolved from our initial concept of the Model Driven Organisation, through to a practical language (ESL) and execution environment for enterprise simulation and now to advances to methodologies for digital twin design.
Along the way, a TCS Research Scientist (Souvik Barat) has completed a doctoral study in the design of a modelling language to support enterprise decision making. This language would later contribute to work by Dr Souvik Barat to design a sociotechnical digital twin of the City of Pune, to support non-pharmaceutical interventions during the Covid-19 pandemic.Â
The ESL Language (lead Prof Tony Clark) developed as a TRL-5 prototype through the collaboration has formed the basis of a TCS TwinXâą software product developed by TCS and is now being used by TCS consulting.
The collaborative research programme has generated over 30 research publications at leading computing conferences and journal publications. Representative publications are listed [2,4,5,6]. The team has also generated impact and knowledge transfer through the production of advanced tutorials and workshops at conferences. The collaboration has also produced an edited book [7].
Recognising the importance of outcomes to the two respective organisations, the research has contributed to executing the research strategy of TCS Research (see strategy document) and has led directly to an impact case study submitted to REF2021.
Further value derived from our inclusive innovation approach has led to developing research publication preparation skills at TCS and even wider social impact through the pandemic planning activities in Pune City [1]. See the video: https://www.youtube.com/watch?v=x48G7-bOvPY).
In 2019, as our research work has steadily shifted towards Digital Twin technologies, Middlesex established the London Digital Twin Research Centre (LDTRC). The centre combines the software engineering research with cyber-physical systems and telecommunications research to present a means of showcasing a range of externally funded Digital Twin research projects. The focus of the centre has been brought to the attention of EPSRC and it holds regular business facing workshops.
Lessons learnt
Developing a strategic collaboration requires: investment from universities; a spirit that places collaboration and not competition at its heart, and willingness from academics to look for long-term benefit. Two senior academics spent three weeks touring Indian IT research labs with no guarantee of success. Hence, alignment with university strategy is critical.
Systemising this model of cooperation should be considered a strategic objective of UK Research and Innovation. A recognition that such success can be found in all our universities is imperative. While the EPSRC and RAE have âvisiting academic-industrial collaboratorâ schemes they could generate much greater outcomes if their scale was smaller and they were genuinely accessible to all academics at all institutions.
References
Barat, Souvik, Ritu Parchure, Shrinivas Darak, Vinay Kulkarni, Aditya Paranjape, Monika Gajrani, and Abhishek Yadav. “An Agent-Based Digital Twin for Exploring Localized Non-pharmaceutical Interventions to Control COVID-19 Pandemic.” Transactions of the Indian National Academy of Engineering 6, no. 2 (2021): 323-353.
Barat, S., Kulkarni, V., Clark, T., Barn, B. (2019) An Actor Based Simulation Driven Digital Twin for Analyzing Complex Business Systems. Proceedings of the 2019 Winter Simulation Conference, 2019, Maryland, USA.(doi:Â 10.1109/WSC40007.2019.9004694)
Clark, T., Barn, B.S. and Oussena, S., 2011, February. LEAP: a precise lightweight framework for enterprise architecture. In Proceedings of the 4th India Software Engineering Conference (pp. 85-94). ACM. (doi:10.1145/1953355.1953366)
Clark, T., Kulkarni, V., Barn, B., France, R., Frank, U. and Turk, D., 2014, January. Towards the model driven organization. In 2014 47th Hawaii International Conference on System Sciences (pp. 4817-4826). IEEE. (doi:10.1109/HICSS.2014.591)
Clark, T., Kulkarni, V., Barat, S. and Barn, B., 2017, June. ESL: an actor-based platform for developing emergent behaviour organisation simulations. In International Conference on Practical Applications of Agents and Multi-Agent Systems (pp. 311-315). Springer, Cham. (doi: https://doi.org/10.1007/978-3-319-59930-4_27 )
Kulkarni, V., Barat, S., Clark, T. and Barn, B., 2015, September. Toward overcoming accidental complexity in organisational decision-making. In 2015 ACM/IEEE 18th International Conference on Model Driven Engineering Languages and Systems (MODELS) (pp. 368-377). IEEE. (doi:10.1109/MODELS.2015.7338268)
Kulkarni, Vinay and Sreedhar Reddy, Tony Clark, and Balbir S. Barn, eds. Advanced Digital Architectures for Model-Driven Adaptive Enterprises. Hershey, PA: IGI Global, 2020. https://doi.org/10.4018/978-1-7998-0108-5
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Associate Prof Graeme Knowles (Director of Education Innovation, WMG), Dr Jane Andrews (Reader in STEM Education Research) and Professor Robin Clark (Dean WMG)
Abstract: The âTransforming Tomorrowâ Project is an example of how educational research may be used to inform and underpin change in engineering education. Building on previous research, the project provides an example of how research and scholarship may be used to effect transformational change by linking industrial requirements with educational strategy and practice. Bringing together theoretically grounded curriculum design with two years of educational research, mainly conducted during the pandemic, the primary output thus far is the development of a series of professional development workshops. Such workshops are aimed at preparing engineering educators to make sure that as WMG emerges out of the pandemic and into a time of unprecedented uncertainty and change, we continue to produce high quality graduates able to âhit the ground runningâ upon entering employment. This short paper summarises the background to the project, discussing the methodology and providing exemplar data whilst also outlining the content of the workshops.
Introduction
WMG has a strong history of providing both practically relevant education and producing graduates who are able to impact the companies they work for from the earliest point of employment. The Departmentâs experience, built up over many years, has come about through the development of strong relationships between WMG colleagues and industry, through mutual understanding and the co-creation of relevant courses. However, as with the whole of the Higher Education Sector, WMG cannot afford to stand still. With the ever-increasing and dynamic demands of the Engineering Sector there is a constant need to reflect and consider whether impactful outcomes are still being realised.
The âTransforming Tomorrowâ Project is about taking a holistic view of the Departmentâs educational provision in order to understand the effectiveness of the provision from studentsâ perspective, whilst also taking account of the views and experiences of staff and industry employers. With the research underway, a number of datasets collected and emergent findings analysed, WMG has the basis with which to begin to affect transformational change both in our educational offerings and also in how we  better meet the needs of industry. This paper reports the first part of the Project.
Context
For many, the pace of change since the onset of Covid19 has been challenging. In WMG, having to completely reconfigure what is an exceptionally industrially focused curriculum and teach online took many by surprise. At the beginning of the Pandemic a critical literature review was undertaken looking at blended and online learning; five key themes were identified:
The need to adopt  a design approach to curriculum development
The quality of the student experience
 Student engagement
The challenges and benefits of blended learning
Student and academic perceptions of online learning
Each of these themes have in common the fact that the virtual learning approaches analysed and  discussed were developed over a significant period of time.  Â
Method and Findings
A mixed methodological approach was utilised starting with a quantitative survey of first year students and staff. This first survey, which took place in October 2021, focused on studentsâ perceptions of what types of learning approaches and techniques they expected to encounter whilst at university. Comprising a mixture of Degree Apprentices and Traditional Engineering undergraduates, the cohort were unique in that they had spent a significant part of their pre-university education learning from home during the lockdown.Â
The results of the survey are given below in Figure 1 and reveal that, during the Pandemic at least, Â engineering undergraduate students start university with the perception that they will be spending much of their time working independently and learning online.
Figure 1: First Year Engineering Studentsâ Expectations of Learning and Teaching at University: Mid-Pandemic (October 2021)
In looking at the above table one thing that immediately drew colleaguesâ attention was that only half of the students expected to frequently encounter active learning approaches, and just under two-fifths anticipated frequently engaging in real-life work-related activities. Having given considerable thought as to how to assure that learning through the Pandemic maintained high levels of both these activities, this took colleagues by surprise. It also suggested  a lack of preparedness, on behalf of the students, to proactively engage in practical engineering focused education.
For the academic staff, a survey conducted at the same time sought to determine colleaguesâ preferences in terms of teaching approaches. Figures 2 and 3 below provide an overview of the answers to two key questionsâŠ
This paper necessarily provides only a small insight into the research findings, in total over 1,300 undergraduate and postgraduate students and over 200 colleagues have participated in the research thus far. Analysing the findings and feeding-forward into the Education and Departmental Executive structures, the findings are being used to shape how education has continued under the lockdown (and will continue into the future). Â With a firm-eye for the ever-changing requirements and expectations of industry, a series of pedagogical workshops grounded in the Project research findings have been developed. The aim of such workshops is to upskill academic colleagues in such a way so as to be able to guarantee that WMG continues to offer industrially relevant education as society moves out of the Pandemic and into an unknown future.
Moving Forward: Scholarship, Synergy & Transformational Change: Meeting the learning and teaching challenges of 21st Century Industry
Planning, the second stage of the Project has meant synthesizing the research findings with organisational strategy and industrial indicators to put in place a series of professional-development workshops for teaching colleagues. Each workshop focuses on a different area of educational practice and considers the needs of industry from a particular standpoint. Plans are underway to use the workshops themselves as opportunities to gather data using an Action Research Methodology and a Grounded Theory Philosophy. The Project is at best estimate, midway through its lifecycle, but may continue for a further two years depending on the Covid situation.
The planned workshops, which will be offered to colleagues throughout the Spring and Summer, 2022, will focus around six distinctive but interlinked topics: Â
1. Teaching to Meet the Challenges of Industry
Contextualising learning in society
Looking back to move forward
Transforming teaching
Producing work-ready graduates when âworkâ is constantly changing.
2. Student-Centred Active Learning
Deep or surface learning?
Engendering independent learning in the millennial student
Co-creation in learning
Encouraging a learning culture
3. Growing independent learners
Developing self-authorship in students (and staff)
Disruptive pedagogies = flexible graduates
Authenticity in assessment
Re-imagining assessment for employability Â
4. Levelling the Playing Field
Supporting students to succeed
Post-colonial industry-focused learning Â
Inclusivity in learning and teaching
Student-led, research-based, real-life teaching
5. Re-Designing what we do
Design thinking for the future
Linking work and education for the millennium generation
Knowledge exchange and co-creation
Embedding sustainability principles across the curriculum
6. Engineering  an environment for learning
Scaffolding active learning across
Finding space for study
Bringing engineering challenges into learning
Off-On-Hybrid: Moving forward from Covid
Conclusion
In conclusion, society is entering what has been termed âthe new normalâ; for WMG, there is nothing ânormalâ about what we do. We are entering a ‘Transformational Timeâ; a period when by completely changing and challenging our educational offerings and culture we will work with our industrial partners to purposefully disrupt the ânew normalâ. In doing so we will continue to produce forward-thinking, flexible and synergetic learning experiences from which highly qualified graduates able to succinctly blend into the workplace will emerge.Â
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professorsâ Council or the Toolkit sponsors and supporters.
Authors: Alex Prince (Sheffield Hallam University) and Prof Wayne Cranton (Sheffield Hallam University)
Keywords: Innovation, SMEs
Abstract: The Sheffield innovation Programme led by Sheffield Hallam with the Growth Hub and the University of Sheffield, delivers bespoke R&D, consultancy and workshops, driving innovation in regional SMEs. In total, since 2016, our experts from across the University have supported over 400 projects with regional businesses, enabling them to grow, diversify and meet changing customer needs. Many projects lead to further collaborations such as KTPs and create new products, processes and market opportunities.
Background
The Sheffield Innovation Programme (SIP) was set up in 2016 to support small and medium sized enterprises (SMEs) from across the South Yorkshire region to access academic expertise, facilities and resources at Sheffield Hallam University and the University of Sheffield, to stimulate innovation and growth and to increase business competitiveness. The focus of this paper is on activities delivered by Sheffield Hallam University.
Sheffield Hallam University leads the programme, and with the ÂŁ3.1m second phase of the programme also introducing two Innovation Advisors working for the Growth Hub. The programme is jointly funded by; the European Regional Development Fund (ERDF), the universities, South Yorkshire Mayoral Combined Authority and the Higher Education Innovation Fund (HEIF), providing support at zero-cost to businesses. It runs until June 2023.
Activities
The programme has now reached a milestone of 400 projects with regional SMEs, enabling them to grow, diversify and meet changing customer needs. To date over 150 academics have worked with companies. Of these 76 staff who are based in Sheffield Hallamâs engineering research centres have worked with 85 companies.Â
SIP supports time for academics to undertake work with clients. It uses funding to enable delivery of R&D consultancy services to the businesses, helping to establish new products or services, resolve problems or advise on appropriate routes forwards.
Outputs
The main output is âbusiness assistâ interventions- a minimum of 12 hours of engagement. These are delivered through bespoke R&D-based consultancy and workshops. The average intervention is approx. 7 days, recognising the potential time required to work with a client meaningfully.
Sheffield Hallam has implemented a light-touch internal approval process for clients where support may take more than 10 days of time. Such investment needs to demonstrate significant added value- for the client in terms of market opportunity or jobs created, or potentially for us also in terms of joint funding proposal development.
SIP has now resulted in 8 successful KTP applications for Sheffield Hallam with more in the pipeline, plus other Innovate UK and commercial consultancy activities, plus considerable reputational benefit regionally.
SIP, Innovation and Engineering expertise
SIP has developed a proven model for collaborating with SMEs, buying out the time of engineers and other academic experts so they can work with companies.
The core areas of academic support are the expertise within the Materials Engineering Research Institute (MERI), the National Centre of Excellence for Food Engineering (NCEFE), and the Sport Engineering Research Group (SERG) and Design Futures (Product and Packaging).
In a region with a very low level of innovation and investment in R&D, the project provides an important entry point to the Universityâs expertise and a platform for longer term projects and creates opportunities for early career researchers, graduate interns and KTP associates. Project delivery connects our engineering expertise with specialisms across the University resulting in collaborations with designers, biosciences and materials, and supports targeted engagement with sectors for example glass and ceramics and the food industry.
Examples:Â
Thermotex Engineering a family-run business which operates in the field of thermodynamics and specialises in manufacturing thermal insulation. The company required physical evidence of how a fabric performed in order to make a bid for a major project based in Arctic Russia. We undertook accelerated weathering testing on the durability of a fabric material when it was exposed to cycles of freezing and thawing, UVB radiation and high temperature / relative humidity. âThis solution provided us with indicative product testing for unusual characteristics, access to laboratory equipment, and performance of specific tests,â said Paige Niehues, the Commercial and Technical Executive at Thermotex Engineering. https://www.shu.ac.uk/research/specialisms/materials-and-engineering-research-institute/what-we-do/case-studies/accelerated-weathering-testing
Sheffield-based SME Safety Fabrications Ltd manufactures fall protection and building access solutions. This includes roof top anchoring systems that allow roped access (e.g., abseiling) at height. The company wanted to develop a new davit arm and socket system that could be used on tall structures to improve rope access for building maintenance. Their unique product idea avoided permanent obstruction on roof tops and allowed for easy installation and removal. MERI worked with Safety Fabrications Ltd to design different davit arm configurations which would satisfy the complex needs of the BS specification. âWorking with engineering specialists within the university allowed us to theoretically explore a range of options prior to manufacture & physical testing.â John Boyle, Managing Director at Safety Fabrications Limited https://www.safetyfabrications.co.uk/
Equitrek provides an excellent example of cross disciplinary working and progression of relationships with a company. In summary our design expertise enabled the company to manufacture new horse boxes targeting entry into the American market and has led to longer term KTPs. The KTP has enabled Equi-Trek to enhance all aspects of their new product development processes, including ergonomics, spatial design, technical analysis and manufacturing.  https://www.shu.ac.uk/news/all-articles/latest-news/hallam-knowledge-transfer-partnership-local-firm-outstanding
Guildhawk employs thousands of translators across the world for hundreds of clients . A project with SIP led to a KTP. At the SHU Innovation Conference 2021. Jurga Zilinskiene MBE, the CEO, told delegates in her keynote address that the KTP helped create an extraordinary SaaS platform that for the first time will help businesses of all sizes to manage people in a fast, easy and secure way. The partnership resulted in the launch of new software products, Guildhawk Aided, Text Perfect and Guildhawk Voice avatars. https://www.fenews.co.uk/education/clean-data-for-ai-at-the-heart-of-industry-4-0-technology-revolution-says-guildhawk-ceo-coder/
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