Abstract
The design of circular products is now a trending topic that involves enabling reuse, repair, refurbishing, remanufacturing, and upgrading parts and products. In this field, using Design For X (DFX) tools appears to be an interesting and helpful way to address requirements and considerations by applying single design rules that can enhance performance in terms of circularity. However, the current DFX approaches are not formally oriented to a circular economy (CE), and there is no clear pathway to apply design rules for circular products. Therefore, this article proposes a classification of DFX rules based on seven CE strategies related to slowing and closing the loop of products, parts, and materials. The proposed approach consisted of a literature review, an analysis of DFX rules related to CE, and the classification of such rules in terms of CE strategies and product design stages. The analysis of DFX rules in product circularity provided insights to generate a specific design guideline of 51 rules for circular products. The guideline was denominated as the Design for Circularity and Durability (DFCD) and is proposed as a design tool for practitioners, designers, and academicians in CE. A case study is also presented to demonstrate the implementation and benefits of the DFCD guideline.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
Circular economy is a growing and trending topic gaining rapid interest in governments, companies, and academies since it is considered a powerful concept to face climate change and resource depletion issues. Products designed to be circular imply an intrinsic design to facilitate restorative mechanism (Tam et al. 2019), which involves the application of several strategies that include upgrade, repair and maintenance, reuse, refurbishing, remanufacture, repurposing, and recycling (Blomsma et al. 2019; Mestre and Cooper 2017). Nevertheless, the integration of CE as a key attribute in the design of products and product families is still a challenge for designers and manufacturers nowadays since the consideration of environmental, economic, societal, and technical impacts across the whole lifecycle involves many considerations, disciplines, and indicators (Aguiar et al. 2022).
Within the different approaches to the design of circular products, the Design for X (DFX) tools are highly recommended by technical and academic literature (Benabdellah et al. 2019; Chiu and Okudan Kremer 2011; Sassanelli et al. 2020a, b) Such an approach consists of guidelines to improve some aspects (enhancing the technical performance in a specific lifecycle stage or a feature or attribute of the product) in the design process. Some of the most studied DFX approaches in previous research are (i) Design for Assembly (DFA) (Boothroyd 1996; Bouissiere et al. 2019; Cabello Ulloa et al. 2018), which is oriented to minimize the cost of assembly within the constraints imposed by the other design features of the product, this method covers fastening selection, symmetry, and size of the parts, angle of insertion among other assembly variables. (ii) Design for Manufacturing (DFM) (Stoll 1988, 1990) consists of a guideline to select manufacturing processes based on physical and geometrical attributes of the part and includes raw material selection, process selection, use of modular design, usage of standardized components, multi-use part development, usage of separate fasteners and assembly direction minimization. (iii) Design for Disassembly (DFD) (Zust and Wagner 1992), which covers the selection of reversible fasteners, the definition of optimal disassembly sequence, modular design to facilitate subassemblies, and disassembly processes, among others. Another approach is the (iv) Design for Recycling (DFR) (Simon 1993), which is also associated with dismantling techniques to facilitate the identification and separation of materials suitable for recycling in terms of entire products and parts once the product reaches its end-of-life stage. Furthermore, (v) Design for Environment (DFE) (J. Fiksel and Wapman 1994) is one of the more comprehensive and relevant design approaches that include topics such as environmental risk management, product safety, occupational health and safety, pollution prevention, ecology, resource conservation, accident prevention, and waste management (J. R. Fiksel 2009; Ross et al. 2022). DFE is commonly aimed at minimizing the use of non-renewable resources, effectively managing renewable resources, and reducing toxic releases to the environment. Similarly, to the DFX approaches, as mentioned earlier, many others have been developed during the last four decades, and now it is possible to find more than 25 approaches with specific applications.
However, despite using different DFX tools or guidelines, there is a lack of approaches formally oriented to circular products. Some guidelines like DFMA and DFE have demonstrated improvement in some aspects of circularity, like the facilitation of disassembly and re-assembly, the use of materials with lower environmental impact, and better recyclability. Furthermore, other approaches like Design for Modularity and Design for Durability contribute to more circular products. Regarding product design, there is a research opportunity in the field of DFX approaches oriented to CE. Specific DFX rules are required to address new product designs and redesigns, especially when companies integrate more circularity into their processes, business models, and markets. Thus, design rules for circularity are required to facilitate the implementation of circularity in the lifecycle of products, parts, and materials. This article aims to contribute to that research direction, proposing a formal DFX approach focused on circular products and considering different CE strategies. Moreover, it provides a proper implementation path of rules to facilitate the transition from linear to circular products, considering the conventional product design process. The research is developed following a literature review and further identifying and classifying specific DFX guidelines contributing to each CE strategy. This research output is a list of guidelines denominated Design for Circularity and Durability (DFCD), which provides different paths of design interventions and considerations to enable the circularity of a physical or tangible product. The circularity aspect considers the ability to generate multiple cycles around different CE strategies, and the durability is considered to last longer without accelerating product replacement. The proposed approach's novelty focuses on two main aspects: (i) defining a set of design rules dedicated to improving the circularity of products. (ii) the classification and organization of such rules according to each stage of the product design process. In practical terms, the DFCD guideline provides a simple and easy-to-follow path to enhance the circularity of existing products or design new products from a more circularity perspective.
The rest of the structure of this article is organized as follows: Sect. 2 consists of the methodology employed to identify, classify, and define specific design guidelines for circular products. Section 3 includes the results after implementing the methodology and summarizes the literature review regarding circularity, DFX approaches, and the identification and classification of guidelines for designing circular products during the product design process. The case study implementation is described in Sect. 4. Findings and discussion are presented in Sect. 5. Lastly, Conclusions and future works are presented in Sect. 6.
2 Methodology
The proposed methodology for the development of the DFCD guideline consisted of three steps: (a) a literature review of attributes or features of circular products and DFX guidelines related to such attributes, and (b) the identification and analysis of DFX guidelines that contribute to the circularity of products, and (c) the identification of individual guidelines or rules for circularity and their classification for each CE strategy during the product design process. The three-phase methodology implemented in this research combines a literature review, a descriptive analysis, and a classification of design rules focused on circular products. Figure 1 shows the methodology to generate the DFCD guideline. Each methodological stage is defined in detail as follows; the results of each stage are later described in Sect. 3.
The first step includes revising previous literature around the DFX concept and the most relevant approaches around the CE concept. This literature search was performed using a systematic approach in the SCOPUS database and combining the results of different search queries. Articles that included rules or guidelines related to resource optimization, complexity reduction, robust design, material selection, and lifecycle impacts were considered in this search. After collecting and analyzing the existing literature, design rules related to circularity were identified using a manual keyword search into the selected articles. Later, different rules of DFA, DFM, DFMA, DFE, and DFR were analyzed and selected regarding their contribution to product circularity (e.g., Implementation of easy-to-use joints in the product facilitates the disassembly and re-assembly of products, therefore contributes to strategies such as repair, upgrade, remanufacture and refurbish; Select materials with high mechanical and chemical durability, especially those which comprise the enclosure or external layer of the product enables the reuse of the product or components).
Once the DFX guidelines were analyzed, the next step was to classify them according to each CE strategy and their application during the design process. At this point, three main phases were proposed for classifying the DFCD rules: The conceptual design stage includes functional analysis, the definition of preliminary product architecture, and the generation and evaluation of concepts. The embodiment design comprises the arrangement of physical functions (product architecture), the preliminary selection of materials, modeling and size of parts, robust design, and the selection of final dimensions/parameters and tolerances. Finally, the detailed design covers the make-buy decisions, the final selection and sizing of components, the generation of engineering drawings, the bill of materials, and prototyping. Design rules were organized in an orderly manner according to the design process steps. The rules were also classified in relevance for each CE strategy.
3 Developing the DFCD guideline
3.1 Literature review
As the first step proposed in the methodology, a non-exhaustive literature review is performed using the SCOPUS database. The results from nine searches based on title, abstract, and keywords were analyzed to obtain a list of selected works related to CE and DFX approaches. As inclusion criteria, articles, books, and conference proceedings published under peer review processes were selected considering the fulfillment of at least one of the following conditions: (i) Combination of CE and product design, (ii) Analysis or implementation of DFX tools, (iii) Combination of CE and DFX approaches. It is important to clarify that other design approaches not formally denominated DFX were considered in the literature search. For example, eco-design conventionally provides design rules or recommendations to reduce the environmental impact of products across their lifecycle. This review process did not include gray literature, technical reports, or secondary information from governments or companies.
Moreover, the approach is limited to academic literature solely. Search queries were generated using the most common and simple words related to the topic of interest. Therefore, 909 entries were obtained from the literature search using the Scopus database. The search had a broad scope since it was necessary to analyze the whole picture regarding DFX approaches and the CE concept. Table 1 summarizes the search topics, the query employed, and the total number of entries and works for each query. From the literature revision, 141 articles were classified as selected works, which after an in-deep revision and duplicate elimination, resulted in 110 highly related articles. These articles were analyzed in detail, providing valuable insights about circular product attributes and CE DFX approaches.
3.1.1 DFX approaches
After analyzing the existing literature, 15 DFX approaches were directly related to the previously mentioned CE strategies after manually revising highly related articles using a word search into each document. DFX approaches that contribute to CE strategies are enlisted and presented as enablers of product circularity. Table 2 shows the relevance (measured on a three-level scale) of each DFX approach versus the seven CE strategies according to different authors. The most relevant approaches identified in the literature were Design for Assembly/Disassembly, Design for Durability, Design for Modularity, and Design for Upgradability. Nevertheless, each DFX approach is related to at least one CE strategy.
3.1.2 Circular products
Circular products are defined as those that operate within the circular economy model. Thus, they are designed to be reused, repaired, refurbished, remanufactured, upgraded, or recycled. However, there are many categories of circular products; some are designed for extended lifespans (i.e., products with high durability like military appliances), and others for short lifespans (i.e., biodegradable packaging). To define circularity in more detail, it is possible to identify which attributes or features define or enable the circularity of products and parts. The literature analysis identified eight attributes as key circular features after a manual and in-deep revision of selected works in which characteristics or features need to be addressed to enable circularity and extended lifespan. Such attributes are assemblability, disassemblability, durability, modularity, simplicity, standardization, commonality, and affordability of spare parts.
Seven strategies are presented in this article following the frameworks proposed by Potting et al. (2017) and Blomsma et al. (2019). Six of them are strategies oriented to extend the lifespan of products and their parts (R1–R6): Upgrade (R1), which involves extending the existing use cycle by adding value or improving the function of a product in comparison to previous versions, this can be esthetic or functional. Repair (R2) covers the repair and maintenance of defective products so they can be used with their original function. Reuse (R3) means the reuse by another consumer of a discarded product that is still in good condition and fulfills its original function. Refurbish (R4) is associated with restoring an old product and bringing it up to date. Remanufacture (R5) involves using parts of a discarded product in a new product with the same function. The Repurpose (R6) strategy covers using a discarded product or its parts in a new product with a different function. Recycling (R7) is also presented as a seventh strategy, but it is related to recirculating material to obtain new raw material for transformation processes. R1–R7 strategy taxonomy followed in this research is proposed considering two primary sources: (i) the circular strategies framework proposed by (Blomsma et al. 2019) and (ii) the multiple life cycle design approach developed by (Mestre and Cooper 2017). Therefore, the definition of CE strategies and design perspectives correspond to those specific approaches. Table 3 summarizes previous research's attributes and their relation to CE strategies.
As a guideline for assessing the product attributes aforementioned in Table 3, a scoreboard summarized in the Table 4 is proposed to assess the product attributes related to circular product design. Similarly, Table 5 is presented as a generic measurement of the relationship between the product attributes and the CE strategies. Scores presented in Table 5 as a generic measurement of circularity but can be modified according to the type of product if necessary. Both Tables 4 and 5 can be applied on case studies to assess the potential of product circularity.
3.2 Identification and analysis of DFX rules related to circular products
From the analysis of the 15 DFX approaches, it was possible to identify and propose 51 rules that can be performed during the design phase of any product or system for enabling CE in general terms (See Table 4). The classification of design rules was developed following three main stages of product design: (i) conceptual design, (ii) embodiment design, and (iii) detailed design.
Rules for conceptual design were oriented to identify potential CE strategies that can be added to the product lifecycle, the generation of more circular conceptual alternatives, and the hierarchization of alternatives considering CE in addition to conventional selection parameters such as functionality, cost, and esthetics, among others. Rules related to embodiment design were focused on two main aspects: the definition of product architecture and geometry and the definition of materials. Such processes consider different CE strategies oriented to extend the product lifespan and enable repairing, refurbishing, remanufacturing, upgrading, and recycling. Lastly, several rules were classified into the detailed design phase, providing relevant considerations to facilitate the circularity of products and parts across their whole lifecycle.
3.3 Definition of design rules for circular and durable products (DFCD)
A progressive route to implement the proposed Design for Circularity and Durability rules is proposed in this subsection after analyzing each rule and its relationship to the seven CE strategies. Thus, the rules were organized following the three-phase design process to provide design criteria and tasks to enable circularity in any of the abovementioned strategies (see Table 6). Design rules are not co-dependent or mandatory, and their application depends on the type of product, the selected CE strategy or strategies, and the flexibility of the development process since manufacturing must provide enough flexibility to perform geometry and material modifications. Table 7 summarizes the design rules according to each CE strategy. The concept of eco-design is relevant to the proposed approach, especially in those rules related to materials; however, it is conventionally limited to environmental issues, and some rules related to biodegradable materials were not included in the DFCD guideline.
4 Case study
The tricycle redesign is presented as a case study for implementing the DFCD guideline (see Fig. 2). The detailed implementation of the DFCD is described as follows in Sect. 4.1, which includes the conceptual design, meanwhile sub Sect. 4.2 describes the implementation of rules for embodiment and detail design.
4.1 Conceptual redesign
In this phase, the first step is determining which CE strategies are the most suitable for the tricycle. Here, rules 101, 102, and 103 are applied to diagnose the tricycle circularity and to select the most suitable strategies that can be applied to it. Figure 3 details the part inventory for the tricycle, while Table 8 summarizes the diagnostic of circularity of the tricycle based on the manufacturing materials, geometric attributes, and joints. Circularity diagnostic is based on a numerical valuation (high–medium–low) of design attributes and their relationship with CE strategies (R1 to R7). Appendix A shows the scores and description for each level.
After inventorying parts of the tricycle and identifying materials, geometries and joints it is possible to determine the CE strategies for the tricycle. The valuation of each product attribute is determined following Table 4, and then is multiplied by the relevance of each CE strategy according to Table 5. Then, the score of each CE strategy is obtained adding up the result of all multiplications between attributes valuation’s and CE strategy relevance.
Table 9 summarizes the score of CE strategies for the case study. In this case, Repair (R2) and Remanufacture (R5) can be suitable for implementation in the tricycle (with scores equal to 38). No secondary functionalities or second-life functions were identified in the tricycle, therefore R6 offers the lower score. Reviewing the commercial solutions around circularity of similar products, it is found that remanufacturing is one of the most relevant strategies implemented, especially in the EU, where companies like Roetz-Bikes (https://roetz-bikes.com/circular) offer remanufacturable bikes. Therefore, remanufacture is selected as the target strategy. However, other CE strategies can be enhanced indirectly since several rules are shared among them.
4.2 Embodiment and detailed redesign
Seven rules for embodiment and four for detailed redesign will be implemented in the tricycle after selecting Remanufacturing as CE target strategy. Table 10 shows the rules selected from the DFCD guideline. Seven rules related to embodiment design and four rules in detailed redesign were selected to demonstrate how them can be implemented in the tricycle. It is important to clarify that more than those 11 rules can be implemented to obtain more circularity in a product; however, in this case study, it is considered a moderate redesign instead a radical one.
Figure 4 shows a graphical description of the 11 DFCD rules selected. A brief description of each rule or set of rules is also included to explain the modification performed on the tricycle. For this case study, materials, joints, thicknesses of structural components, identification marks and modularity comprise the redesign modification.
Implementation of rules 206 and 207 enable higher durability of pedals, which are commonly exposed to wear, impact and dynamic loads. As a drawback, the use of a metallic material increases the mass of the tricycle. Rules 213, 216, 218 and 220 are directly related to modifications in the joints employed in the tricycle, the use of standardized butterfly nuts facilitates the manual assembly and disassembly, which is a key issue to support repairing, remanufacturing, refurbishing and upgrading. The modification related to rule 221 involves an increase in the mass of the tricycle; however, it enables the future remanufacturing (polishing, cleaning) and guarantee an increase in reliability. Rules 306, 208, and 312 facilitate the rapid identification of parts that can be remanufactured in the case of extended lifespan or recycled in the case of material recirculation. Finally, implementation of rule 310 increases the functional performance of the tricycle, which can have different accessories (hopper or additional chair).
5 Findings and discussion
Five major findings can be remarked on from the literature analysis and the consolidation of the DFCD rules based on DFX approaches. Such findings are described in detail as follows:
From the literature review—no DFX approaches are massively linked to the development of circular products. Thus, the existing rules focus on improving product design, manufacturing, use, and final disposal stages. Nevertheless, circular design involves two considerations that are not commonly considered in the conventional design process: the extension of product lifespan through durable components, the ability to be dismantled for enabling repair, refurbishing, and remanufacturing, which is denominated “To extend loops” and the second one denominated “To close loops” (Bocken et al. 2016) which implies that the product can be reintegrated to new use cycles and not necessarily after a useful life, the case of products easy to recycle or easy to biodegrade are examples of this. Therefore, DFCD guideline proposed in this study is limited to specific resource consumption and improvements from a conventional design perspective based on attributes of circular products and not from a broader point of view from CE, with all the environmental, economic, and social implications derived from that concept. It is important to clarify that circular attributes mentioned in this research (assemblability, disassemblability, durability, modularity, simplicity, standardization, commonality, and affordability of spare parts) are complimentary and do not compete with conventional ones (functionality, cost, etc.). Thus, circular products involve more attributes of features compared to conventional products, therefore their design process involve more complexity and rigor since the lifecycle performance is largely settled during the design phase.
The DFCD rules were based on conventional DFX approaches such as Design for Manufacturing and Assembly (Boothroyd 1996; Bouissiere et al. 2019; British Standard BS8887-2-2009 Design for Manufacture, Assembly, Disassembly and End-of-Life Processing (MADE) 2009; Hsu and Lin 2002; Urrutia et al. 2014), Ecodesign ((Luttropp and Lagerstedt 2006); Design for Environment (J. R. Fiksel 1996; J. Fiksel and Wapman 1994); Design for Sustainability (Arnette et al. 2014; Ko 2020; Ljungberg 2007; Page 2014); Design for lifecycle and EOL (Cappelletti et al. 2022; Hapuwatte et al. 2022; Rogkas et al. 2021; Zikopoulos 2022) among others. Such rules lie in the reduction of materials, optimization of geometry, increase of reliability and functional/performance enhancing. Therefore, some rules are directly associated with reduction of energy and mass consumption during extraction of raw materials and processing as well. In the case of extended lifespan strategies like repair, refurbish, and remanufacture, DFX rules (from DFA, DFM, Design for modularity) enable a more flexible lifecycle to reuse parts and components. However, more rules can be obtained depending on focusing issues like: (i) the type of product (i.e., electronical, mechanical); (ii) the industry (i.e., energy related products, automotive, aerospacial, mining, construction) and, (iii) the business model strategy of the company (i.e., leasing, refurbishing, repairing, remanufacturing, product as a service platform among others).
Regarding CE strategies, reuse (R3) and repurpose (R6) have an important research gap compared to other strategies. In the case of reuse, more research is required related to the selection of durable materials, robust design, and product lifecycle management, but it also demands other interventions in consumer behavior to ensure that products can last as long as they can. Concerning repurposing, the challenge is complex since secondary or tertiary functionalities need to be included from the early design stages (product architecture) and the user is responsible for using such functionalities in a repurpose scenario. Some approaches were oriented to specific CE strategies like upgrading(Nurhasyimah et al. 2016; Umemori et al. 2002; Xing and Belusko 2008), repairing (Sabbaghi and Behdad 2017), remanufacturing (Ijomah et al. 2007), recycling (Ferro and Bonollo 2019; Leal et al. 2020). However, there is no connection between design rules and the product design process. Conventionally, design contributions are presented without formally considering the stage of design that applies for their implementation or are presented for a specific stage, which is the conceptual design.
The proposed design rules for CE involve the combination of different DFX approaches and tasks to ensure or improve circularity during the design process. However, such rules must be carefully addressed to avoid constraints and contradictions during the selection of materials and the definition of geometrical parameters. Thus, several rules cannot be fully applied simultaneously without establishing a trade-off or pros and cons analysis. For example, a robust design can involve fewer components. Meanwhile, modularization involves the separation of functionalities into individual components or modules. This situation can be studied from the optimization perspective and depends on the product type and the CE strategy target. As a challenging barrier, the integration of geometry and material rules for more circular products is evident, especially for complex products comprised of several subassemblies. In terms of applicability, the DFCD guideline is proposed initially for tangible products, services and product-service systems were not included in the scope of the research. Nevertheless, it can be interesting for future works to create a framework for software and services similar to DFCD following CE strategies.
While the DFCD rules were identified and classified, it was identified that there is a need for more research regarding specific CE strategies. Some general approaches, such as DFMA, DFA, and DFM, can be applied to several CE strategies like repair, remanufacturing, refurbishing, and upgrading, but the main objective of such approaches is not product circularity. Thus, some DFX rules can be used with demonstrated success in the product design process, but it is necessary to develop specific rules for circular products not only for redesign approaches but also for new product developments. As an interesting topic for future research, the development of DFC rules for different types of products (electronical appliances, furniture, plastic products, and building components, among others) appears as a vast research field with potential for academic studies and industrial applications. In addition, industry 4.0 tools can significantly enhance product circularity from a broader perspective. Thus, the analysis of design modifications throughout the whole lifecycle (manufacturing, use, final disposal) can generate resource savings and predict product functionality issues and potential failures.
Regarding the case study implementation, it is clear that DFCD rules in the conceptual design phase require more design efforts and resources, since they involve diagnostic, ideation, and conceptualization of preliminary alternatives. The tricycle case study was developed as a redesign process; therefore, it is possible that new designs demand more rules and a specific approach to avoid design conflicts and confusion during their implementation. It is possible to implement more than the 11 rules included in the case study. Nevertheless, the case study was used as a demonstrative example of how rules can be implemented. Thus, more radical redesigns can be generated and therefore a better circularity performance of the tricycle.
Rules concerning embodiment and detailed design have a more technical implementation and can be proved without complexity in products. However, the rules need to be addressed step by step in more complex products where small modifications involve drastic performance results in product functionality (i.e., automotive industry). As was demonstrated in the tricycle case study, many rules can be applied; however, the designer or design team need to prioritize which ones are suitable and relevant in terms of circularity or added value. The proposed approach can be replicated for future works related to new design for circularity rules following the methodology proposed in this article: literature review (not exhaustive) about DFX + analysis of circularity in product design, identifying DFX rules applicable to circular design and proposing specific rules for circularity. However, design rules for circularity can be obtained from other sources following scientific approaches like surveys, interviews, focus groups and discussions among academy, industry, and policymakers.
6 Conclusion
This article first reviewed the literature around DFX approaches related to the CE concept to define a guideline or set of design rules to facilitate the implementation of CE strategies within the product design process as complementary attributes to conventional ones (resistance, functionality, or cost). Despite several DFX guidelines covering some circularity, there is a lack of specific guidelines for circular products and their proper implementation during the design or redesign process. As a second contribution of this article, a characterization of existing DFX rules is proposed to define a route of implementation towards the product design process in its primary design phases (conceptual, embodiment, and detailed). As a result, 51 rules were proposed and classified according to the different CE strategies; Upgrade (R1), Repair and Maintenance (R2), Reuse (R3), Refurbish (R4), Remanufacture (R5), Repurpose (R6), and Recycle (R7). Such rules comprise the design for circularity and durability—DFCD, which is proposed as an engineering tool to include or improve circularity during the design of products. The DFCD guideline offers a unique path of rules depending on the selected CE strategy and involves both geometrical and material selection considerations.
In future works, more research efforts are expected to consolidate specific circularity rules for each CE strategy and analyze constraints and potential conflicts in the simultaneous implementation of rules. Integrating industry 4.0 technologies into the product design process is necessary to facilitate the lifecycle analysis of parts and products once the design rules are applied and their overall impact on sustainability. Similarly, design rules for non-tangible products like software and services must be generated to cover CE issues related to resource consumption and sustainability performance.
Data availability
The author declarse that the data supporting the findings of this study are available within the article.
References
Aguiar MF, Mesa JA, Jugend D, Pinheiro MAP, Fiorini PDC (2022) Circular product design: strategies, challenges and relationships with new product development. Manag Environ Qual Int J 33(2):300–329. https://doi.org/10.1108/MEQ-06-2021-0125
Arnette AN, Brewer BL, Choal T (2014) Design for sustainability (DFS): the intersection of supply chain and environment. J Clean Prod 83:374–390. https://doi.org/10.1016/j.jclepro.2014.07.021
Asif FMA, Roci M, Lieder M, Rashid A (2021) A methodological approach to design products for multiple lifecycles in the context of circular manufacturing systems. J Clean Prod. https://doi.org/10.1016/j.jclepro.2021.126534
Bakker C, Wang F, Huisman J, den Hollander M (2014) Products that go round: exploring product life extension through design. J Clean Prod 69:10–16. https://doi.org/10.1016/j.jclepro.2014.01.028
Bauer T, Zwolinski P, Nasr N, Mandil G (2020) Characterization of circular strategies to better design circular industrial systems. J Remanuf 10:161–176
Benabdellah AC, Bouhaddou I, Benghabrit A, Benghabrit O (2019) A systematic review of design for X techniques from 1980 to 2018: concepts, applications, and perspectives. Int J Adv Manuf Technol 102(9–12):3473–3502. https://doi.org/10.1007/s00170-019-03418-6
Berwald A, Dimitrova G, Feenstra T, Onnekink J, Peters H, Vyncke G, Ragaert K (2021) Design for circularity guidelines for the EEE sector. Sustainability (switzerland). https://doi.org/10.3390/su13073923
Bigerna S, Micheli S, Polinori P (2021) New generation acceptability towards durability and repairability of products: circular economy in the era of the 4th industrial revolution. Technol Forecasting Soc Change 165:120558
Blomsma F, Pieroni M, Kravchenko M, Pigosso DCA, Hildenbrand J, Rùna A, Kristoffersen E, Shahbazi S, Li J, Wiik C, Due K, Anna-karin J, Mcaloone TC (2019) Developing a circular strategies framework for manufacturing companies to support circular economy-oriented innovation. J Clean Prod 241:118271. https://doi.org/10.1016/j.jclepro.2019.118271
Bocken NMP, de Pauw I, Bakker C, van der Grinten B (2016) Product design and business model strategies for a circular economy. J Ind Prod Eng 33(5):308–320. https://doi.org/10.1080/21681015.2016.1172124
Boothroyd G (1996) Design for manufacture and assembly: the Boothroyd-Dewhurst experience. Design for X. Springer Netherlands, pp 19–40. https://doi.org/10.1007/978-94-011-3985-4_2
Bouissiere F, Cuiller C, Dereux PE, Malchair C, Favi C, Formentini G (2019) Conceptual design for assembly in aerospace industry: a method to assess manufacturing and assembly aspects of product architectures. Proceedings of the international conference on engineering design. ICED, pp 2961–2970. https://doi.org/10.1017/dsi.2019.303
Bracquene E, Peeters JR, Burez J, de Schepper K, Duflou JR, Dewulf W (2019) Repairability evaluation for energy related products. Procedia CIRP 80:536–541. https://doi.org/10.1016/j.procir.2019.01.069
Bracquené E, Peeters J, Alfieri F, Sanfélix J, Duflou J, Dewulf W, Cordella M (2021) Analysis of evaluation systems for product repairability: a case study for washing machines. J Clean Prod 281:125122. https://doi.org/10.1016/j.jclepro.2020.125122
Brissaud D, Zwolinski P (2017) The scientific challenges for a sustainable consumption and production scenario: the circular reuse of materials for the upgrading and repurposing of components. Procedia CIRP 61:663–666. https://doi.org/10.1016/j.procir.2016.11.148
Cabello Ulloa MJ, Remirez Jauregui A, ZulaikaMunain I, AreitioaurtenaOiartzun M, RetolazaOjanguren I, Campos Insunza MA, Martínez Noguera F (2018) New integrative approach to existing design for assembly (DFA) methodologies: application on elevator components. Proceedings of international design conference, DESIGN. Cambridge University Press, pp 215–224. https://doi.org/10.21278/idc.2018.0381
Cappelletti F, Rossi M, Germani M (2022) How de-manufacturing supports circular economy linking design and EoL—a literature review. J Manuf Syst 63:118–133. https://doi.org/10.1016/j.jmsy.2022.03.007
Chiu MC, Okudan Kremer GE (2011) Investigation of the applicability of design for X tools during design concept evolution: a literature review. Int J Prod Dev 13(2):132–167. https://doi.org/10.1504/IJPD.2011.038869
Chouinard U, Pigosso DCA, McAloone TC, Baron L, Achiche S (2019) Potential of circular economy implementation in the mechatronics industry: an exploratory research. J Clean Prod. https://doi.org/10.1016/j.jclepro.2019.118014
Chunhua F, Shi H, Guozhen B (2020) A group decision making method for sustainable design using intuitionistic fuzzy preference relations in the conceptual design stage. J Clean Prod 243:118640. https://doi.org/10.1016/j.jclepro.2019.118640
Cordella M, Al F, Clemm C, Berwald A (2021) Durability of smartphones: A technical analysis of reliability and repairability aspects. J Clean Prod 286:125388. https://doi.org/10.1016/j.jclepro.2020.125388
Coughlan D, Fitzpatrick C, Mcmahon M (2018) Repurposing end of life notebook computers from consumer WEEE as thin client computers e A hybrid end of life strategy for the Circular Economy in electronics. J Clean Prod 192:809–820. https://doi.org/10.1016/j.jclepro.2018.05.029
de Los Rios IC, Charnley FJS (2017) Skills and capabilities for a sustainable and circular economy: the changing role of design. J Clean Prod 160:109–122. https://doi.org/10.1016/j.jclepro.2016.10.130
de Almeida ST, Borsato M, Lie Ugaya CM (2017) Application of exergy-based approach for implementing design for reuse: the case of microwave oven. J Clean Prod 168:876–892. https://doi.org/10.1016/j.jclepro.2017.09.034
den Hollander MC, Bakker CA, Hultink EJ (2017) Product design in a circular economy: development of a typology of key concepts and terms. J Ind Ecol 21(3):517–525. https://doi.org/10.1111/jiec.12610
Ferro P, Bonollo F (2019) Design for recycling in a critical raw materials perspective. Recycling. https://doi.org/10.3390/recycling4040044
Fiksel JR (1996) Achieving eco-efficiency through design for environment. Total Qual Environ Manag. https://doi.org/10.1557/S0883769400056645
Fiksel JR (2009) Design for environment: a guide to sustainable product development. Sust Dev 212:410. https://doi.org/10.1002/sd.171
Fiksel J, Wapman K (1994) How to design for environment and minimize life cycle cost. Proceedings of 1994 IEEE international symposium on electronics and the environment. IEEE
Franco MA (2019) A system dynamics approach to product design and business model strategies for the circular economy. J Clean Prod 241:118327. https://doi.org/10.1016/j.jclepro.2019.118327
Geng J, Tian X, Bai M, Jia X, Liu X (2014) Computers in Industry A design method for three-dimensional maintenance, repair and overhaul job card of complex products. Comput Ind 65(1):200–209. https://doi.org/10.1016/j.compind.2013.08.008
Go TF, Wahab DA, Hishamuddin H (2015) Multiple generation lifecycles for product sustainability: the way forward. J Clean Prod 95:16–29. https://doi.org/10.1016/j.jclepro.2015.02.065
Haines-Gadd M, Chapman J, Lloyd P, Mason J, Aliakseyeu D (2018) Emotional durability design nine-A tool for product longevity. Sustainability (switzerland) 10(6):1–19. https://doi.org/10.3390/su10061948
Hallack E, Peris NM, Lindahl M, Sundin E (2022) Systematic design for recycling approach - automotive exterior plastics. Procedia CIRP 105:204–209. https://doi.org/10.1016/j.procir.2022.02.034
Hapuwatte BM, Badurdeen F, Bagh A, Jawahir IS (2022) Optimizing sustainability performance through component commonality for multi-generational products. Resour Conserv Recycl. https://doi.org/10.1016/j.resconrec.2021.105999
Haziri LL, Sundin E (2020) Supporting design for remanufacturing—a framework for implementing information feedback from remanufacturing to product design. J Remanuf 10:57–76
Hsu H, Lin GCI (2002) Quantitative measurement of component accessibility and product assemblability for design for assembly application. Robot Comput Integr Manuf 18:13–27
Ijomah WL, McMahon CA, Hammond GP, Newman ST (2007) Development of design for remanufacturing guidelines to support sustainable manufacturing. Robot Comput Integr Manuf 23(6):712–719. https://doi.org/10.1016/j.rcim.2007.02.017
Inkermann D (2022) Lifecycle option selection in early design stages based on degradation model evaluation. Proc Design Soc 2:475–484. https://doi.org/10.1017/pds.2022.49
Ishigami Y, Yagi H, Kondoh S, Umeda Y, Shimomura Y, Yoshioka M (2008) Development of a design methodology for upgradability involving changes of functions. Springer, pp 235–242. https://doi.org/10.1109/vetecf.2003.240538
Kaddoura M, Kambanou ML, Tillman AM, Sakao T (2019) Is prolonging the lifetime of passive durable products a low-hanging fruit of a circular economy? A multiple case study. Sustainability (switzerland). https://doi.org/10.3390/su11184819
Kampker A, Wessel S, Fiedler F, Maltoni F (2021) Battery pack remanufacturing process up to cell level with sorting and repurposing of battery cells. J Remanuf 11:1–23
Ko Y-T (2020) Modeling an innovative green design method for sustainable products. Sustainability 12(8):3351. https://doi.org/10.3390/su12083351
Krystofik M, Luccitti A, Parnell K, Thurston M (2018) Adaptive remanufacturing for multiple lifecycles: a case study in office furniture. Resour Conserv Recycl 135:14–23. https://doi.org/10.1016/j.resconrec.2017.07.028
Kwak M, Kim HM (2011) Assessing product family design from an end-of-life perspective. Eng Optim 43(3):233–255. https://doi.org/10.1080/0305215X.2010.482990
Laitala K, Klepp IG, Haugrønning V, Throne-holst H (2021) Increasing repair of household appliances, mobile phones and clothing: experiences from consumers and the repair industry. J Clean Prod 282:125349. https://doi.org/10.1016/j.jclepro.2020.125349
Leal JM, Pompidou S, Charbuillet C, Perry N (2020) Design for and from recycling: a circular ecodesign approach to improve the circular economy. Sustainability (switzerland) 12(23):1–30. https://doi.org/10.3390/su12239861
Li Y, Xue D, Gu P (2008) Design for product adaptability. Concurr Eng Res Appl 16(3):221–232. https://doi.org/10.1177/1063293X08096178
Ljungberg LY (2007) Materials selection and design for development of sustainable products. Mater Des 28(2):466–479. https://doi.org/10.1016/j.matdes.2005.09.006
Luttropp C, Lagerstedt J (2006) EcoDesign and the ten golden rules: generic advice for merging environmental aspects into product development. J Clean Prod 14(15–16):1396–1408. https://doi.org/10.1016/j.jclepro.2005.11.022
Manelius A, Nielsen S, Kauschen JS (2019) Rebeauty—artistic strategies for repurposing material components. IOP Conf Ser Earth Environ Sci. https://doi.org/10.1088/1755-1315/225/1/012023
Mesa J, Maury H, Arrieta R, Bula A, Riba C (2015) Characterization of modular architecture principles towards reconfiguration: a first approach in its selection process. Int J Adv Manuf Technol. https://doi.org/10.1007/s00170-015-6951-3
Mesa JA, Esparragoza I, Maury H (2018) Development of a metric to assess the complexity of assembly/disassembly tasks in open architecture products. Int J Prod Res 56(24):7201–7219. https://doi.org/10.1080/00207543.2017.1398431
Mesa J, González-quiroga A, Maury H (2020) Developing an indicator for material selection based on durability and environmental footprint: a circular economy perspective. Resour Conserv Recycl 160(April):104887. https://doi.org/10.1016/j.resconrec.2020.104887
Mesa JA, Gonzalez-Quiroga A, Aguiar MF, Jugend D (2022) Linking product design and durability: a review and research agenda. Heliyon. Elsevier Ltd. https://doi.org/10.1016/j.heliyon.2022.e10734
Mestre A, Cooper T (2017) Circular product design. A multiple loops life cycle design approach for the circular economy. Design J 20(sup1):S1620–S1635. https://doi.org/10.1080/14606925.2017.1352686
Moreno M, de Los Rios C, Rowe Z, Charnley F (2016) A conceptual framework for circular design. Sustainability (switzerland). https://doi.org/10.3390/su8090937
Nurhasyimah AA, Dzuraidah AW, Rizauddin R (2016) Evaluating design for upgradability at the conceptual design stage. Jurlna Teknologi 78(6–9):37–43
Offerman E (2019) Critical materials: underlying causes and sustainable mitigation strategies. World Scientific
Page T (2014) Product attachment and replacement: implications for sustainable design. Int J Sust Design 2(3):265. https://doi.org/10.1504/ijsdes.2014.065057
Pialot O, Millet D (2014) Why upgradability should be considered for rationalizing materials? Procedia CIRP 15:379–384. https://doi.org/10.1016/j.procir.2014.06.013
Potting J, Hekkert M, Zamagni A (2017) Circular Economy: measuring innovation in the product chain. PLB Publishers
Raihanian A, Esmaeilian B, Cade W, Wiens K, Behdad S (2016) Mining consumer experiences of repairing electronics: Product design insights and business lessons learned. J Clean Prod 137:716–727. https://doi.org/10.1016/j.jclepro.2016.07.144
Rogkas N, Tsolakis E, Kalligeros C, Vasileiou G, Vakouftsis C, Kaisarlis G, Markopoulos AP, Spitas V (2021) Upcycling obsolete mechanical equipment into innovative laboratory test rigs: a low-cost solution or a sustainable design approach? Proc Design Soc 1:3309–3318. https://doi.org/10.1017/pds.2021.592
Ross D, Ferrero V, DuPont B (2022) Exploring the effectiveness of providing structured design-for-the-environment strategies during conceptual design. J Mech Design Trans ASME. https://doi.org/10.1115/1.4052513
Sabbaghi M, Behdad S (2017) Design for repair: A game between manufacturer and independent repair service provider. Proc ASME Design Eng Tech Conf 2A–2017:1–9. https://doi.org/10.1115/DETC2017-67986
Saidani M, Yannou B, Leroy Y, Cluzel F (2020) Dismantling, remanufacturing and recovering heavy vehicles in a circular economy—Technico-economic and organisational lessons learnt from an industrial pilot study. Resour Conserv Recycl 156(November 2018):104684. https://doi.org/10.1016/j.resconrec.2020.104684
Sassanelli C, Urbinati A, Rosa P, Chiaroni D, Terzi S (2020a) Addressing circular economy through design for X approaches: a systematic literature review. Comput Ind 120:103245. https://doi.org/10.1016/j.compind.2020.103245
Sassanelli C, Urbinati A, Rosa P, Chiaroni D, Terzi S (2020b) Computers in Industry Addressing circular economy through design for X approaches: a systematic literature review. Comput Indust 120:103245. https://doi.org/10.1016/j.compind.2020.103245
Shahbazi S, Jönbrink AK (2020) Design guidelines to develop circular products: action research on nordic industry. Sustainability (switzerland) 12(9):1–14. https://doi.org/10.3390/su12093679
Simon M (1993) Objective assessment of designs for recycling. Proceedings of 9th international conference on engineering design. ICED, pp 832–835
Singhal D, Tripathy S, Kumar S (2020) Remanufacturing for the circular economy: study and evaluation of critical factors. Resour Conserv Recycl 156(2018):104681. https://doi.org/10.1016/j.resconrec.2020.104681
British Standards Institution. (2009). BS 8887-2:2009 Design for Manufacture, Assembly, Disassembly, and End-of-Life Processing (MADE) - Part 2: Design of Product and its Parts for Economic and Efficient Manufacture. London, UK
Stoll H (1990). In: Allen CW (ed) Design for manufacturing, simultaneous engineering. SME Press
Stoll HW (1988) Design for manufacture. Tools and manufacturing engineers handbook: manufacturing management, vol 5, pp 13-1-13-32. SME Press
Sumter D, Bakker C, Balkenende R (2018) The role of product design in creating circular business models: a case study on the lease and refurbishment of baby strollers. Sustainability (switzerland). https://doi.org/10.3390/su10072415
TalensPeiró L, Ardente F, Mathieux F (2017) Design for disassembly criteria in EU product policies for a more circular economy: a method for analyzing battery packs in PC-tablets and subnotebooks. J Ind Ecol 21(3):731–741. https://doi.org/10.1111/jiec.12608
Tam E, Soulliere K, Sawyer-Beaulieu S (2019) Managing complex products to support the circular economy. Resour Conserv Recycl 145(February):124–125. https://doi.org/10.1016/j.resconrec.2018.12.030
Türkeli S, Huang B, Stasik A, Kemp R (2019) Circular economy as a glocal business activity: mobile phone repair in the Netherlands, Poland and China. Energies. https://doi.org/10.3390/en12030498
Umemori Y, Kondoh S, Umeda Y, Shimomura Y, Yoshioka M (2002) Design for upgradable products considering future uncertainty. Proceedings second international symposium on environmentally conscious design and inverse manufacturing. IEEE, pp 87–92
Urrutia UA, Webb P, Summers M (2014) Analysis of design for X methodologies for complex assembly processes: a literature review. V004T06A009. https://doi.org/10.1115/DETC2014-34955
Venkatachalam V, Pohler M, Spierling S, Nickel L, Barner L, Endres HJ (2022) Design for recycling strategies based on the life cycle assessment and end of life options of plastics in a circular economy. Macromol Chem Phys. https://doi.org/10.1002/macp.202200046
Wagner E, Bracquen E, Jaeger-erben M (2021) Exploring 14 years of repair records e information retrieval, analysis potential and data gaps to improve reparability. J Clean Prod 281:125259. https://doi.org/10.1016/j.jclepro.2020.125259
Xing K, Belusko M (2008) Design for upgradability algorithm: configuring durable. J Mech Design Trans ASME 130(November 2008):1–14. https://doi.org/10.1115/1.2976446
Yang SS, Ong SK, Nee AYC (2016) A decision support tool for product design for remanufacturing. Procedia CIRP 40:144–149. https://doi.org/10.1016/j.procir.2016.01.085
Yang SS, Nasr N, Ong SK, Nee AYC (2017) Designing automotive products for remanufacturing from material selection perspective. J Clean Prod 153:570–579. https://doi.org/10.1016/j.jclepro.2015.08.121
Zikopoulos C (2022) On the effect of upgradable products design on circular economy. Int J Prod Econ. https://doi.org/10.1016/j.ijpe.2022.108629
Zust R, Wagner R (1992) Approach to the identification and quantification of environmental effects during product life. Annals of the CIRP 4(1):473–476
Acknowledgements
The author would like to acknowledge Vicerrectoría de Investigación, Creación e Innovación Universidad del Norte (Colombia) for the funding to develop this research.
Funding
Open Access funding provided by Colombia Consortium.
Author information
Authors and Affiliations
Contributions
The author confirms sole responsibility for the following: study conception and design, data collection, analysis and interpretation of results, and manuscript preparation
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Conflict of interest
The author has no competing interests to declare relevant to this article's content.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Mesa, J.A. Design for circularity and durability: an integrated approach from DFX guidelines. Res Eng Design 34, 443–460 (2023). https://doi.org/10.1007/s00163-023-00419-1
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00163-023-00419-1