Abstract
In the paradigm of industry 4.0, manufacturing enterprises need a high level of agility to adapt fast and with low costs to small batches of diversified products. They also need to reduce the environmental impact and adopt the paradigm of the circular economy. In the configuration space defined by this duality, manufacturing systems must embed a high level of reconfigurability at the level of their equipment. Finding the most appropriate concept of each reconfigurable equipment that composes an eco-smart manufacturing system is challenging because every system is unique in the context of an enterprise’s business model and technological focus. To reduce the entropy and to minimize the loss function in the design process of reconfigurable equipment, an evolutionary algorithm is proposed in this paper. It combines the particle swarm optimization (PSO) method with the theory of inventive problem-solving (TRIZ) to systematically guide the creative potential of design engineers towards the definition of the optimal concept over equipment’s lifecycle: what and when you need, no more, no less. The algorithm reduces the number of iterations in designing the optimal solution. An example for configuration design of a reconfigurable machine tool with adjustable functionality is included to demonstrate the effectiveness of the proposed algorithm.
Highlights
In the configuration space defined by this duality, manufacturing systems must embed a high level of reconfigurability at the level of their equipment
Particle swarm optimization (PSO) algorithms prove effective for handling nonlinear spaces with discontinuities [48,59,60]
For conceptualizing the reconfigurable machine tool, in this case, study, we selected a set of engineering key performance indicators (E-KPIs) that come in front of the paradigms of industry 4.0 and circular economy
Summary
The circular economy, in symbiosis with industry 4.0, aims to transform the manufacturing industry into a more sustainable one from economic, ecologic, and social points of view by changing the paradigm in which business models and offers are designed, developed, produced, delivered, consumed, and withdrawn [2]. Lifecycle thinking, eco-innovation, stewardship, transparency and traceability, system thinking, and tight collaboration in the value chains are key principles of the circular economy [3]. The following subsections briefly describe two topics relevant to this paper. They are referring to particle swarm intelligence and structured innovation. The theory of particle swarm intelligence was proposed by [45] to solve some optimization problems in engineering. Particle swarm optimization (PSO) algorithms prove effective for handling nonlinear spaces with discontinuities [48,59,60].
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