Circular Systems Engineering: A Novel Paradigm for Sustainable Systems Design, Development, and Lifecycle Management
Conceitos Básicos
Circular systems engineering is a novel paradigm that adopts the circularity principle of circular economy to enable truly sustainable systems engineering practices.
Resumo
The paper introduces the concept of circular systems engineering, a novel paradigm for systems sustainability. It defines two key principles to implement circular systems engineering:
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End-to-end sustainability: Reasoning about sustainability must scale from the scope of single engineering activities to the overall engineering process and networks of processes. This allows for assessing sustainability and finding trade-offs across the entire value chain.
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Bipartite sustainability: Sustainable systems and sustainable engineering methods are equally important and form an inseparable unit when assessing sustainability. Incurring sustainability debts along the engineering process might render the overall systems engineering endeavor unsustainable.
The paper outlines typical organizational evolution patterns that lead to the implementation and adoption of circularity principles, and highlights key challenges and research opportunities for the modeling community in supporting circular systems engineering. These include:
- End-to-end process modeling and enactment methods to assess and optimize sustainability across engineering process networks
- Modeling and simulation techniques to comprehensively evaluate the sustainability of systems and engineering methods, and find trade-offs among different sustainability goals
- Leveraging digital enablers like digital twins to govern end-to-end processes and support sustainability objectives
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Circular Systems Engineering
Estatísticas
The paper reports the following key statistics:
Manufacturing industries account for nearly a third of the global energy consumption and produce 36% of CO2 emissions worldwide.
The ICT sector currently contributes to about 2-4% of global CO2 emissions, which is projected to increase to about 14% by 2040.
The ICT sector should decrease its CO2 emissions by 42% by 2030, 72% by 2040, and 91% by 2050 to align with the rest of the economy.
The amount of discarded electrical or electronic devices, known as e-waste, is recognized by the World Economic Forum as the fastest-growing category of waste.
Citações
"The environmental impacts of systems engineering are particularly apparent. Manufacturing industries account for nearly a third of the global energy consumption and produce 36% of CO2 emissions worldwide."
"Information and Communications Technology (ICT), which systems engineering heavily relies on, currently contributes to about 2-4% of global CO2 emissions, comparable to the carbon emissions of the avionics sector. Without intervention, this number is projected to increase to about 14% by 2040."
"The amount of discarded electrical or electronic devices, known as e-waste, is recognized by the World Economic Forum as the fastest-growing category of waste."
Perguntas Mais Profundas
How can circular systems engineering principles be effectively integrated into existing systems engineering frameworks and methodologies?
Circular systems engineering principles can be effectively integrated into existing systems engineering frameworks and methodologies by following a structured approach:
Education and Training: Organizations need to educate their teams about the principles of circular systems engineering and the importance of sustainability. Training programs can help employees understand how to apply these principles in their work.
Incorporating Sustainability Metrics: Integrate sustainability metrics into existing systems engineering frameworks. This includes assessing the environmental, social, economic, and technical sustainability aspects of the systems being developed.
Lifecycle Thinking: Adopt a lifecycle approach to systems engineering, considering sustainability throughout the entire lifecycle of a system - from design and development to operation, maintenance, and retirement.
Collaboration and Communication: Encourage collaboration between different departments and stakeholders to ensure that sustainability goals are aligned and integrated into the overall systems engineering process.
Tools and Technologies: Utilize tools and technologies that support circular systems engineering, such as digital twins, simulation tools, and data analytics platforms to optimize for sustainability.
Continuous Improvement: Implement a culture of continuous improvement, where feedback on sustainability performance is collected, analyzed, and used to make iterative enhancements to the systems engineering process.
By following these steps, organizations can effectively integrate circular systems engineering principles into their existing frameworks and methodologies, leading to more sustainable and environmentally friendly systems.
How can the concepts of digital twins and digital threads be leveraged to enable the end-to-end and bipartite sustainability principles of circular systems engineering?
Digital twins and digital threads can play a crucial role in enabling the end-to-end and bipartite sustainability principles of circular systems engineering:
End-to-End Sustainability: Digital twins provide a virtual representation of physical systems, allowing for real-time monitoring, analysis, and optimization of sustainability performance throughout the entire lifecycle of a system. By leveraging digital twins, organizations can track sustainability metrics, identify areas for improvement, and make data-driven decisions to enhance sustainability.
Bipartite Sustainability: Digital threads facilitate the seamless flow of information and data across different stages of the systems engineering process. By integrating sustainability considerations into digital threads, organizations can ensure that sustainability goals are embedded in the design, development, operation, and maintenance of systems. This holistic approach enables the sustainability of both the engineered system and the engineering methods used.
Data-Driven Decision Making: Digital twins and digital threads provide a wealth of data that can be analyzed to optimize sustainability performance. By leveraging advanced analytics and AI algorithms, organizations can identify sustainability trade-offs, simulate different scenarios, and make informed decisions to achieve both end-to-end and bipartite sustainability goals.
Continuous Monitoring and Improvement: Digital twins enable continuous monitoring of sustainability performance, allowing organizations to track progress, identify deviations from sustainability targets, and implement corrective actions in real-time. This iterative approach to sustainability management ensures that systems and methods are continuously improved to align with circular systems engineering principles.
By harnessing the power of digital twins and digital threads, organizations can enhance their sustainability efforts, drive innovation, and achieve long-term environmental, social, and economic benefits in line with circular systems engineering principles.
What are the potential barriers and challenges in getting organizations to adopt a circular systems engineering mindset, and how can these be overcome?
Adopting a circular systems engineering mindset can be challenging for organizations due to various barriers and obstacles:
Lack of Awareness: Many organizations may not fully understand the concept of circular systems engineering and its benefits. Educating stakeholders about the importance of sustainability and the value of circularity is crucial to overcoming this barrier.
Resistance to Change: Implementing new principles and methodologies can face resistance from employees who are comfortable with existing practices. Change management strategies, training programs, and clear communication can help address this resistance.
Cost Considerations: Transitioning to circular systems engineering may require initial investments in new technologies, training, and processes. Organizations need to weigh the long-term benefits of sustainability against the short-term costs.
Complexity and Integration: Integrating sustainability considerations into existing systems engineering frameworks can be complex and challenging. Organizations need to develop clear roadmaps, establish cross-functional teams, and collaborate closely to ensure successful integration.
Regulatory Compliance: Meeting regulatory requirements related to sustainability and environmental impact can pose challenges for organizations. Staying informed about regulations, engaging with regulatory bodies, and implementing robust compliance processes are essential.
Data Management and Analysis: Leveraging digital twins and digital threads for sustainability requires effective data management and analysis capabilities. Organizations need to invest in data infrastructure, analytics tools, and skilled personnel to extract meaningful insights from data.
To overcome these barriers and challenges, organizations can take the following steps:
Develop a clear sustainability strategy aligned with circular systems engineering principles.
Engage stakeholders at all levels to build buy-in and commitment to sustainability goals.
Invest in training and upskilling programs to equip employees with the knowledge and skills needed for circular systems engineering.
Collaborate with industry partners, experts, and research institutions to stay informed about best practices and emerging trends in sustainability.
Continuously monitor and evaluate sustainability performance, adjust strategies as needed, and celebrate successes to maintain momentum and motivation.