Authors: Maryam Lamere, Marianthi Leon, Wendy Fowles-Sweet, Lucy Yeomans,  Laura Fogg-Rogers (University of the West of England, UWE Bristol). 

Topic: Opportunities and challenges for integrating ESD into engineering programmes via PBL. 

Tool type: Guidance. 

Relevant disciplines: Any.  

Keywords: Education for sustainable development; Project-based learning; Problem-based learning; Engineering design; Sustainability; AHEP; UK-SPEC; Pedagogy; Higher education; Curriculum. 
 
Sustainability competency: Critical thinking; Integrated problem-solving, Collaboration.

AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.  

Related SDGs: SDG 4 (Quality education); SDG 13 (Climate action). 
 
Reimagined Degree Map Intervention: More real-world complexity; Active pedagogies and mindset development.

Who is this article for? This article should be read by educators at all levels in higher education who are seeking an overall perspective on using PBL for integrating sustainability in engineering education. Engaging with this topic will also help to prepare students with the soft skill sets that employers are looking for. 

 

Premise: 

Engineering graduates are increasingly required to implement sustainability-focussed initiatives within industry, alongside enhanced expectations from professional bodies and the UK specification (UK-SPEC) for engineers (Engineering Council, 2024). However, a recent study of UK Higher Education institutions highlighted that only a handful have implemented Education for Sustainable Development (ESD) into their curricula in a systemic manner (Fiselier et al., 2018), which suggests many engineering institutions still need support in this area. This article aims to explain opportunities and challenges for integrating ESD into engineering programmes via project-based learning. 

 

 1. An overview of problem-based learning as a tool for teaching sustainability within engineering:

To develop sustainability-literate graduates, the Higher Education Academy (AdvanceHE) and the UK Quality Assurance Agency for Higher Education (QAA) emphasise that students need to:  

  1. understand what the concept of environmental stewardship means for their discipline and their professional and personal lives; 
  2. think about issues of social justice, ethics, and wellbeing, and how these relate to ecological and economic factors; and 
  3. develop a future-facing outlook by learning to think about the consequences of actions, and how systems and societies can be adapted to ensure sustainable futures (QAA & HEA, 2014).  

Problem-Based Learning (PBL) provides a suitable teaching method for addressing these educational objectives. It is an influential approach in engineering education that emphasises real-world problem-solving and student-centred investigation. PBL deeply engages engineering students, prompting them to develop higher-level thinking skills while they personally confront and navigate economic, social, and environmental issues. This method fosters holistic systems thinking, interdisciplinary insights, ethical considerations, and an emphasis on the long-term viability of technical solutions (Cavadas and Linhares, 2023), while also inspiring and motivating learners (Loyens, 2015). 

While PBL can be delivered through theoretical case study examples, the term is used interchangeably with Project-Based Learning within engineering education. Both problem-based learning and project-based learning share characteristics such as collaboration and group work, the integration of knowledge and practice, and foregrounding problem analysis as the basis of the learning process (De Graaff and Kolmos, 2003). One of the main differences is where the parameters lie: with problem-based learning the parameters are defined at the beginning and students are able to find a range of solutions; with project-based learning the parameters lie at the end and students are expected to reach a specific end solution (Savery, 2006). There is also a difference in the role of the tutor and the information they provide: in problem-based learning the tutor facilitates but gives little information, while in project-based learning they are both a facilitator and a source of knowledge (Savery, 2006). Project based learning may be more accepted within engineering education since it is considered to more closely resemble the reality of the profession (Perrenet, Bouhuijs and Smits, 2000), hence Aalborg’s working definition of PBL as “Problem-Oriented, Project-Organized, Learning” (Dym et al., 2005) 

PBL thus facilitates the creation of immersive student-centric environments where group projects enable collaborative learning (Kokotsaki, Menzies and Wiggins, 2016). As Lozano et al. (2017) highlight, the nature of PBL advances critical thinking and problem-solving in engineering contexts, enabling students to critically reflect on sustainability concepts and apply this understanding to real-world challenges. Importantly, it is paramount in engineering education to foster action-oriented competencies and incorporate social contextualisation aspects (Fogg-Rogers et al., 2022), such as ethical nuances, justice, and equality, ensuring a comprehensive grasp of an engineer’s role amidst evolving societal and environmental challenges (Wang et al., 2022).  

 

2. Overcoming challenges within PBL:

While PBL presents an obvious approach for embedding sustainability, there are a series of challenges which engineering educators need to overcome to facilitate transformational learning. This section presents some of the most common challenges encountered, along with pedagogic solutions.  

 

Lack of apparent topic relevance
Sustainability topics can sometimes be treated as isolated topics, rather than an integrated aspect of an engineering problem. A perception of sustainability in engineering is that it is not implicit in design, manufacture, and operation; rather it is often perceived as an ‘add-on’ to technical skill development. This applies to both students and teachers: both require support to understand the relevance and complexities of sustainability. When academics delivering sustainability materials may struggle to relate the topic to their own engineering disciplines, students may fail to see how they can impact change. Students must work on real-world projects where they can make a difference locally or globally, and they are more inclined towards sustainability topics that are relevant to their subject discipline with subject experts.  

 

Dealing with an overwhelming amount of information
Students can be overwhelmed by the large amounts of multidisciplinary information that needs to be processed when tackling real-world problems. This can also be a challenge for academics delivering teaching, especially if the topic is not related to their speciality. Additional support (and training), along with allocation of teaching workload, are needed to successfully integrate sustainability contexts for both staff and students.   

 

Group work challenges
PBL is best conducted by mixing individual study and group work. However, groups can fail if group creation, monitoring, supporting, and assessing processes are inconsistent, or not understood by academic tutors or students. Tutors need to act as group facilitators to ensure successful collaborative learning.  

 

Issues with continual engagement
PBL often requires active engagement of students over an extended period (several weeks or months). This can be a challenge, as over time, students’ focus and priorities can change. We suggest that whole programmes need to be designed around PBL components, so that other modules and disciplines provide the scaffolding and knowledge development to the relevant PBL topics.  

 

Delivering PBL online 

PBL is best delivered using experiential hands-on learning. For example, at UWE Bristol, this is provided through civic engagement with real-world industry problems and service learning through engagement with industry, schools, and community groups (Fogg-Rogers et al., 2017). This experiential learning was exceptionally challenging to deliver online during the COVID-19 pandemic, and programmes would need to be re-designed for online learning. 

 

3. Recommendations for successful implementation of PBL:

Sustainability topics need to be embedded within engineering education so that each discipline-specific engineering problem is explored within PBL from a technical, economic, ethical, and sustainability perspective.  Drawing from UWE Bristol’s journey of ESD implementation using PBL, key recommendations are outlined below.  

 

Managing academic workload
In the initial phases of ESD integration at UWE Bristol, a small number of committed academics contributed a lot of time, effort, and dedication to push through and enable ESD acceptance from staff and students. Programme-wide implementation of ESD required wider support at the institutional level, alongside additional support for module leaders and tutors, so they felt capable of delivering ESD with a realistic workload. 

 

Structured delivery of ESD
Structuring delivery over time and throughout different modules enables students to work through large amounts of information. Providing summative feedback/assessments during key phases of the PBL exercise can also help students stay on track and manage their workload. At UWE Bristol, group presentations with pass/fail grading are introduced mid-project, so students can present information gathered about the context, before beginning problem-solving. 

 

Managing group work challenges
PBL is best conducted by mixing individual study and group work. Ensuring assessment briefs have implicit sustainability requirements is vital to embedding ESD concepts, so that students can see the need for engagement. This is further enhanced by stating the relevance to workplace contexts and UK-SPEC requirements. Tutors need to facilitate group dynamics and engagement, along with providing support structures for students who, for whatever reason, are unable to engage with group work.  

 

Creating an enabling environment for ESD integration
The integration of sustainable development throughout the curricula at UWE Bristol has been supported at the institutional level, and this has been critical for the wide scale rollout. An institution-wide Knowledge Exchange for Sustainability Education (KESE) network was created to support staff by providing a platform for knowledge sharing. Within the department, Staff Away days were used to run sustainability workshops to discuss ESD and topics of interest to students. An initial mapping exercise was conducted to highlight where sustainability was already taught within the curriculum and to identify the discipline relevant contexts (Lamere et al., 2022). Further training and industrially relevant contexts were provided to convince some staff that sustainability needed to be included in the curriculum, along with evidence that it was already of great relevance in the wider engineering workplace. This led to the development of an integrated framework of key learning requirements which embedded professional attributes and knowledge of the UK-SPEC.  

 

Student motivation and continual engagement  

For sustainability education to be effective, the content coverage should be aligned, or better still, integrated, with the topics that form part of students’ disciplinary studies. To maintain continual engagement during the PBL delivery and beyond, clear linkages need to be provided between learning and future career-related practice-based sustainability activities. Partnerships have been developed with regional stakeholders and industry, to provide more context for real-world problems and to enable local service learning and community action (Fogg-Rogers, Fowles-Sweet, 2018). Industry speakers have also been invited to contribute to lectures, touching on a wide range of sustainability and ethical issues. ESD teaching is also firmly linked to the individual’s own professional development, using the UK-SPEC competency requirements, and linked to end-point assessments. This allows students to see the potential impact on their own professionalism and career development. 

 

These recommendations can enable engineering educators to integrate sustainability topics within the curriculum using PBL to enhance student learning and engagement.  

 

References:  

Cavadas, B., Linhares, E. (2023). ‘Using a Problem-Based Learning Approach to Develop Sustainability Competencies in Higher Education Students’, in Leal Filho, et al. W., Azul, A.M., Doni, F., Salvia, A.L. (eds) Handbook of Sustainability Science in the Future. Springer, Cham. (Accessed 05 February 2024) 

De Graaff, E. and Kolmos, A. (2003) ‘Characteristics of Problem-Based learning’. International Journal of Engineering Education. 19 (5), pp. 657–662. 

Dym, C.L., et al.  Agogino, A.M., Eris, O., Frey, D.D. and Leifer, L.J. (2005) ‘Engineering design thinking, teaching, and learning’. Journal of engineering education. 94 (1), pp. 103–120. 

Engineering Council (2024). UK-SPEC Fourth Edition. (Accessed 05 February 2024).  

Fogg-Rogers, L., Lewis, F., & Edmonds, J. (2017). ‘Paired peer learning through engineering education outreach’, European Journal of Engineering Education, 42(1). (Accessed 05 February 2024).   

Fogg Rogers, L., & Fowles-Sweet, W. (2018). ‘Engineering and society: Embedding active service learning in undergraduate curricula’, in J. Andrews, R. Clark, A. Nortcliffe, & R. Penlington (Eds.), 5th Annual Symposium of the United Kingdom & Ireland Engineering Education Research Network (125-129). Aston University 

Fogg-Rogers, L., Bakthavatchaalam, V., Richardson, D., & Fowles-Sweet, W. (2022). ‘Educating engineers to contribute to a regional goal of net zero carbon emissions by 2030’. Cahiers COSTECH, 5, Article 133 

Fiselier, E. S., Longhurst, J. W. S., & Gough, G. K. (2018). ‘Exploring the current position of ESD in UK higher education institutions.’ International Journal of Sustainability in Higher Education, 19(2), 393–412.  

Kokotsaki, D., Menzies, V. and Wiggins, A. (2016) ‘Project-based learning: A review of the literature.’ Improving Schools. 19 (3), pp. 267–277. 

Lamere, M., Brodie, L., Nyamapfene, A., Fogg-Rogers, L., & Bakthavatchaalam, V. (2022). ‘Mapping and enhancing sustainability literacy and competencies within an undergraduate engineering curriculum’ in 9th Research in Engineering Education Symposium and 32nd Australasian Association for Engineering Education Conference (REES AAEE 2021) (298-306) 

Lozano, R., Merrill, M.Y., Sammalisto, K., Ceulemans, K. and Lozano, F.J. (2017), ‘Connecting competences and pedagogical approaches for sustainable development in higher education: a literature review and framework proposal’, Sustainability, Vol. 9 No. 10, pp. 1889-1903. 

Perrenet, J.C., Bouhuijs, P.A.J and Smits, J.G.M.M. (2000) ‘The Suitability of Problem based Learning for Engineering Education: Theory and practice.’ Teaching in Higher Education. 5 (3) pp.345-358. 

QAA & HEA. (2014). Education for sustainable development: guidance for UK higher education providers. Retrieved from Gloucester, UK. 

Savery, J.R. (2006) Overview of Problem-based Learning: Definitions and Distinctions.  The Interdisciplinary Journal of Problem-based Learning. 1 (1), pp. 9–20. 

Wang, Y., Sommier, M. and Vasques, A. (2022), ‘Sustainability education at higher education institutions: pedagogies and students’ competences’, International Journal of Sustainability in Higher Education, Vol. 23 No. 8, pp. 174-193.  

 

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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 Professors’ Council or the Toolkit sponsors and supporters. 

 

To view a plain text version of this document, click here to download the PDF.

Authors: Emma Crichton CEng MICE and Dr Jonathan Truslove MEng PhD (Engineers Without Borders UK). 

Topic: How to talk about sustainability in engineering education. 

Tool type: Guidance. 

Relevant disciplines: Any. 

Keywords: Advocacy; Collaboration; Global responsibility; Sustainability; Systems change; Climate change; AHEP; Higher education; Pedagogy. 
 
Sustainability competency: Self-awareness; Strategic; Critical thinking.

AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.  

Related SDGs: SDG 4 (Quality education); SDG 11 (Sustainable cities and communities); SDG 13 (Climate action). 
 
Reimagined Degree Map Intervention: Active pedagogies and mindset development.

Who should read this article? This article should be read by educators at all levels of higher education looking to embed and integrate sustainability into curriculum design. It’s especially useful in helping educators, heads of departments and deans to engage in a constructive or uncomfortable conversation if you don’t see yourself as a sustainability expert.  

 

Premise: 

To not have conversations because they make you uncomfortable is the definition of privilege. Your comfort is not at the centre of this discussion. That’s not how it works. We have to be able to choose courage over comfort, we have to be able to say, ‘Look, I don’t know if I’m going to nail this but I’m going to try because I know what I’m sure as hell not going to do is stay quiet.’” Brene Brown  

 

Some of the best conversations you can have in life are not comfortable to initiate: 

Think about a time you’ve participated in a meaningful conversation. These are not easy conversations, but they can also be the ones we look back to as very powerful, even if they took courage to initiate. And sometimes in a conversation, especially a constructive conversation, people disagree. People debate. People have different perspectives. And that’s the beauty of conversation and the beautiful rich diversity of people. It would be so boring if we all had the same life experiences, expertise and thoughts. If we only wanted to hear our own perspective, you can do that in a voice note to yourself, in your journal or by talking to the mirror.  

There can also be different conversations depending on the values of those having the conversation. What they see as important, scary or what environment they live in helps form their core understanding. But despite our differences, humans are hard-wired for connection, to listen and talk with others. We discuss ideas in order to find common ground, and/or to learn about an experience we didn’t have ourselves. Difficult, constructive conversations build relationships, while avoiding them leads to a less deep connection.  

 

Why talk about sustainability? 

Educators, you have permission to start and facilitate a conversation about something you don’t know much about or are not an expert in. Just be honest about what you know and be driven to learn more.    

This relates to conversations around the topic of sustainability. When we talk about how we can live within our planetary limits, whilst meeting the needs of all people, questions about justice, inequality and fairness often crop up. We don’t have one right answer here, we don’t have a magic fix or one person to blame. No one is an expert here. Sure, some know more about the science, others more about people’s lived experiences and others can feel they don’t know enough. But we all have a right to participate in conversations about our collective humanity. For example, conversations you could have with students about sustainability could cover: 

After all, sustainability is about imagining our future: One where we have less impact on our safe climate and biodiversity and less inequality. But we may see that future world differently. We may worry about the impact any change might have on our lives and the things we value most. Some may struggle with the idea of repurposing golf courses to address our housing crisis, others may struggle with the idea of policies stopping people from flying frequently (but they might be okay with this being imposed on those with private jets). Others may despair at the slow levels of change, where we don’t move from our default trajectory and risk climate breakdown.  

On our current trajectory, we are looking at living in a world where our climate exceeds 1.5 degrees of warming, where there is mass migration, sea level rise, etc. This world may be worse, where more people suffer. But would you change how we engineer to make it better or play a role in another way to shift our trajectory? 

 

How to initiate conversations about sustainability in engineering education: 

To not have these important conversations means we don’t see any role for ourselves or the organisations we work for in creating change – and that’s not true, since sustainability requires systemic change to how we engineer AND to how we educate. For example, we asked hundreds of engineering educators and educationalists what they hope to see as the future of engineering education. Their responses are visualised below: 

Discussing your opinions about these responses could be one way to start a conversation with a colleague. 

It is also really important to engage in regular conversations about sustainability with students as a feature of their university education. Be a role model for how to participate in constructive conversations respectfully. Help them practise how to hold and present themselves in these spaces.  

So, with this in mind, what can you do?  

 
Initiate the conversation. Prepare to do so. Here are some tips and tricks.  

Be humble! Learning from others is key. Degrees can be designed so that students can frequently hear and learn about different perspectives and develop the ability to speak with economists, social scientists, scientists, humanities experts, ecologists, and those with expertise gained through lived experience. Be willing to learn from others and acknowledge that it’s okay they don’t have all the answers either. In our experience, students usually respect this attitude of humility.  

It can be helpful to work with those with experience. Recognise who is leading changes and creating ways for educators to feel safe in leading and making change. Sometimes all it takes is the offer of a coffee with a colleague to form a connection and get a shared understanding of how to move forward. 

Seek (and give) advice and share your experience. Share resources, barriers, insights and position initiatives to support in an organised and collaborative way.  

Work in partnership with students. Students also have a critical role to play in this shift, not just because they are increasingly demanding to see more sustainability in the curriculum. For many emerging students, sustainability is the topic of their lifetime. Listen to the perspectives of international students, who can bring more diverse perspectives on global responsibility.  

 

Sustainability is more than a word or concept, it is actually a culture, and if we aim to see it mirrored in the near future, what better way exists than that of planting it in the young hearts of today knowing they are the leaders of the tomorrow we are not guaranteed of? It is possible.” 2021 South African university student (after participating in the Engineering for People Design Challenge during their degree course) 

 

Useful resources to get talking: 

There are some excellent resources out there that can help us get started framing and having conversations about sustainability with others: 

1. The Talk Climate Change campaign tracks climate discussions to share messages and inspire others around the world. It provides advice, conversation starters and allows you to add your discussions with family, friends, and communities about sustainability to their interactive map and explore conversations submitted by others. 

2. Listen to podcasts such as the Liberating Sustainability podcast by Students Organising for Sustainability UK (SOSUK) who bring together leaders from student liberation movements and academia to deconstruct the exclusivity of sustainability activism and education, or An Idiot’s Guide to Saving the World which dives into each of the Sustainable Development Goals and focuses in on ‘who is affected?’, ‘What are solutions on a global scale?’, and ‘what can I as an individual do?’. 

3. Watch the presentation on Imagining 2050 from James Norman, a current educator (who will be 72 years old in 2050) and Cleo Parker, an engineering student (who will be 49 in 2050) during the Institution of Structural Engineers Annual Academics Conference 2022. You can also read the main learning points from the conference in this blog post 

4. The World Café methodology is an example of creating a space for collaborative dialogue around questions that matter and sharing insights and lessons learned. You can see an example of this by the UK Green Building Council (UKGBC) who run Collaboration Cafes on Climate Resilience, here. 

5. Watch the TED talks playlists on sustainability covering key questions and visionary ideas on the question of our generation.  

 

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License. 

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 Professors’ Council or the Toolkit sponsors and supporters.

 

To view a plain text version of this resource, click here to download the PDF.

Authors: Dr Gilbert Tang; Dr Rebecca Raper (Cranfield University). 

Topic: Considering the SDGs at all stages of new robot creation. 

Tool type: Guidance. 

Relevant disciplines: Computing; Robotics; Electrical; Computer science; Information technology; Software engineering; Artificial Intelligence; Mechatronics; Manufacturing engineering; Materials engineering; Mechanical engineering; Data. 

Keywords: SDGs; AHEP; Sustainability; Design; Life cycle; Local community; Environment; Circular economy; Recycling or recycled materials; Student support; Higher education; Learning outcomes. 

Sustainability competency: Systems thinking; Anticipatory; Critical thinking.

AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.  

Related SDGs: SDG 9 (Industry, innovation, and infrastructure); SDG 12 (Responsible consumption and production). 

Reimagined Degree Map Intervention: Adapt and repurpose learning outcomes; More real-world complexity.

Who is this article for? This article is for educators working at all levels of higher education who wish to integrate Sustainability into their robotics engineering and design curriculum or module design. It is also for students and professionals who want to seek practical guidance on how to integrate Sustainability considerations into their robotics engineering. 

 

Premise:  

There is an urgent global need to address the social and economic challenges relating to our world and the environment (Raper et al., 2022). The United Nations Sustainable Development Goals (SDGs) provide a framework for individuals, policy-makers and industries to work to address some of these challenges (Gutierrez-Bucheli et al., 2022). These 17 goals encompass areas such as clean energy, responsible consumption, climate action, and social equity. Engineers play a pivotal role in achieving these goals by developing innovative solutions that promote sustainability and they can use these goals to work to address broader sustainability objectives. 

Part of the strategy to ensure that engineers incorporate sustainability into their solution development is to ensure that engineering students are educated on these topics and taught how to incorporate considerations at all stages in the engineering process (Eidenskog et al., 2022). For instance, students need not only to have a broad awareness of topics such as the SDGs, but they also need lessons on how to ensure their engineering incorporates sustainable practice. Despite the increased effort that has been demonstrated in engineering generally, there are some challenges when the sustainability paradigm needs to be integrated into robotics study programs or modules (Leifler and Dahlin, 2020). This article details one approach to incorporate considerations of the SDGs at all stages of new robot creation: including considerations prior to design, during creation and manufacturing and post-deployment. 

 

1. During research and problem definition:

Sustainability considerations should start from the beginning of the engineering cycle for robotic systems. During this phase it is important to consider what the problem statement is for the new system, and whether the proposed solution satisfies this in a sustainable way, using Key Performance Indicators (KPIs) linked to the SDGs (United Nations, 2018), such as carbon emissions, energy efficiency and social equity (Hristov and Chirico, 2019). For instance, will the energy expended to create the robot solution be offset by the robot once it is in use? Are there long-term consequences of using a robot as a solution? It is important to begin engagement with stakeholders, such as end-users, local communities, and subject matter experts to gain insight into these types of questions and any initial concerns. Educators can provide students with opportunities to engage in the research and development of robotics technology that can solve locally relevant problems and benefit the local community. These types of research projects allow students to gain valuable research experience and explore robotics innovations through solving problems that are relatable to the students. There are some successful examples across the globe as discussed in Dias et al., 2005. 

 

2. At design and conceptualisation:

Once it is decided that a robot works as an appropriate solution, Sustainability should be integrated into the robot system’s concept and design. Considerations can include incorporating eco-design principles that prioritise resource efficiency, waste reduction, and using low-impact materials. The design should use materials with relatively low environmental footprints, assessing their complete life cycles, including extraction, production, transportation, and disposal. Powered systems should prioritise energy-efficient designs and technologies to reduce operational energy consumption, fostering sustainability from the outset. 

 

3. During creation and manufacturing:

The robotic system should be manufactured to prioritise methods that minimise, mitigate or offset waste, energy consumption, and emissions. Lean manufacturing practices can be used to optimise resource utilisation where possible. Engineers should be aware of the importance of considering sustainability in supply chain management to select suppliers with consideration of their sustainability practices, including ethical labour standards and environmentally responsible sourcing. Robotic systems should be designed in a way that is easy to assemble and disassemble, thus enabling robots to be easily recycled, or repurposed at the end of their life cycle, promoting circularity and resource conservation. 

 

4. Deployment:

Many robotic systems are designed to run constantly day and night in working environments such as manufacturing plants and warehouses. Thus energy-efficient operation is crucial to ensure users operate the product or system efficiently, utilising energy-saving features to reduce operational impacts. Guidance and resources should be provided to users to encourage sustainable practices during the operational phase. System designers should also implement systems for continuous monitoring of performance and data collection to identify opportunities for improvement throughout the operational life. 

 

5. Disposal:

Industrial robots have an average service life of 6-7 years. It is important to consider their end-of-life and plan for responsible disposal or recycling of product components. Designs should be prioritised that facilitate disassembly and recycling (Karastoyanov and Karastanev, 2018). Engineers should identify and safely manage hazardous materials to comply with regulations and prevent environmental harm. Designers can also explore options for product take-back and recycling as part of a circular economy strategy. There are various ways of achieving that. Designers can adopt modular design methodologies to enable upgrades and repairs, extending their useful life. Robot system manufacturers should be encouraged to develop strategies for refurbishing and reselling products, promoting reuse over disposal. 

 

Conclusion: 

Sustainability is not just an option but an imperative within the realm of engineering. Engineers must find solutions that not only meet technical and economic requirements but also align with environmental, social, and economic sustainability goals. As well as educating students on the broader topics and issues relating to Sustainability, there is a need for teaching considerations at different stages in the robot development lifecycle. Understanding the multifaceted connections between sustainability and engineering disciplines, as well as their impact across various stages of the engineering process, is essential for engineers to meet the challenges of the 21st century responsibly.  

 

References: 

Dias, M. B., Mills-Tettey, G. A., & Nanayakkara, T. (2005, April). Robotics, education, and sustainable development. In Proceedings of the 2005 IEEE International Conference on Robotics and Automation (pp. 4248-4253). IEEE. 

Eidenskog, M., Leifler, O., Sefyrin, J., Johnson, E., & Asplund, M. (2023). Changing the world one engineer at a time–unmaking the traditional engineering education when introducing sustainability subjects. International Journal of Sustainability in Higher Education, 24(9), 70-84.  

Gutierrez-Bucheli, L., Kidman, G., & Reid, A. (2022). Sustainability in engineering education: A review of learning outcomes. Journal of Cleaner Production, 330, 129734. 

Hristov, I., & Chirico, A. (2019). The role of sustainability key performance indicators (KPIs) in implementing sustainable strategies. Sustainability, 11(20), 5742. 

Karastoyanov, D., & Karastanev, S. (2018). Reuse of Industrial Robots. IFAC-PapersOnLine, 51(30), 44-47. 

Leifler, O., & Dahlin, J. E. (2020). Curriculum integration of sustainability in engineering education–a national study of programme director perspectives. International Journal of Sustainability in Higher Education, 21(5), 877-894. 

Raper, R., Boeddinghaus, J., Coeckelbergh, M., Gross, W., Campigotto, P., & Lincoln, C. N. (2022). Sustainability budgets: A practical management and governance method for achieving goal 13 of the sustainable development goals for AI development. Sustainability, 14(7), 4019. 

SDG Indicators — SDG Indicators (2018) United Nations (Accessed: 19 February 2024) 

 

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.  

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 Professors’ Council or the Toolkit sponsors and supporters. 

 

To view a plain text version of this resource, click here to download the PDF.

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