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Design issues concerning circular economy assessment methods at the product level: a comparative analysis through a case study of a mobile tiny house

Published online by Cambridge University Press:  05 June 2024

Laura Ruiz-Pastor
Affiliation:
Department of Mechanical Engineering and Construction, Universitat Jaume I, Castelló de la Plana, Spain Faculty of Engineering, Free University of Bozen-Bolzano, Bolzano, Italy
Stefania Altavilla
Affiliation:
Independent researcher, Graz, Austria
Yuri Borgianni*
Affiliation:
Faculty of Engineering, Free University of Bozen-Bolzano, Bolzano, Italy
*
Corresponding author Yuri Borgianni [email protected]
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Abstract

Sustainability evaluations are increasingly relevant in the design of products. Within sustainability-related frameworks, circular economy (CE) has gained attention in the last few years, and this has vastly affected design, leading, for example, to design for circularity. This article deals with the wide range of product-level CE assessment tools, out of which some are applied to a case study from the building sector, namely a tiny house made with hemp bricks. Attention was specifically paid to those methods through which a single circularity indicator could be extrapolated. Overall, the objective of this work is to study the convergence of existing CE assessment methods in providing consistent circularity performances. The results show similarities in the overall circularity scores despite differences in the variables used to achieve that final score. Thus, despite the lack of standard methods, the results suggest that many of these tools are sufficiently interchangeable, also in consideration of consistent indications to improve the circularity of the tiny house. This means that consistent inputs are provided to anyone willing to redesign the tiny house with the objective of making it more circular irrespective of the assessment tool used.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

The impact of human activities on natural resources is considered a threat to their preservation. The development and manufacturing of products is a primary example of human activities implying the exploitation of natural resources. In this article, the term “product” is intended in a broad sense to mean any physical object and artifact designed to satisfy human needs, that is, including both industrial items and buildings.

As a result of the impact of product development, design is one of the key players in addressing the mentioned sustainability challenges (Buchanan Reference Buchanan2001). Through design, the new products have to keep their original aspect and functions as long as possible (den Hollander, Bakker, & Hultink Reference den Hollander, Bakker and Hultink2017). To this aim, the principles of the circular economy (CE) are gaining traction in the realm of design. According to Bhamra & Hernandez (Reference Bhamra and Hernandez2021), the focus on CE in design is due to its capability to work as an umbrella concept including the most acknowledged eco-design principles and objectives, from cradle-to-cradle to eco-efficiency. Kim et al. (Reference Kim, Cluzel, Leroy, Yannou and Yannou-Le Bris2020) highlight how eco-design is conducive to CE and that the two domains share similar goals. This has led to the proliferation of methods ascribable to “design for CE” and “design for circularity,” which have been recently reviewed and classified (Mesa Reference Mesa2023; Stölzle, Roth & Kreimeyer Reference Stölzle, Roth and Kreimeyer2023).

The attention to be paid to CE determines new challenges, required knowledge areas and skills for designers (Sumter et al. Reference Sumter, de Koning, Bakker and Balkenende2020; Dokter, Thuvander & Rahe Reference Dokter, Thuvander and Rahe2021), who play an important role in the introduction of CE in the industry and the society at large (Golinska et al. Reference Golinska, Kosacka, Mierzwiak and Werner-Lewandowska2015; Kefayati & Moztarzadeh Reference Kefayati and Moztarzadeh2015). As design choices to be made in numerous phases have considerable effects on most CE-oriented acknowledged R strategies (Muñoz, Hosseini & Crawford Reference Muñoz, Hosseini and Crawford2024), the focus on circularity and its measurement are both critical and clearly required. CE assessment is ultimately relevant for the correct implementation of CE principles (Azapagic & Perdan Reference Azapagic and Perdan2000; Bocken et al. Reference Bocken, Olivetti, Cullen, Potting and Lifset2017; Valenzuela-Venegas et al. Reference Valenzuela-Venegas, Salgado and Díaz-Alvarado2016; Vinante et al. Reference Vinante, Sacco, Orzes and Borgianni2021). Cottafava and Ritzen (Reference Cottafava and Ritzen2021) stress the need to accurately assess CE performances in the building industry to evaluate how designs have been successful in material recovery. The assessment of product circularity is also critical to companies that attempt to benefit from the opportunities enabled by CE-related policies (Saidani et al. Reference Saidani, Yannou, Leroy and Cluzel2017a). Contextually, it has to be highlighted that sustainability-oriented assessment methods do not overlap with techniques meant to measure CE. In the literature, some authors have compared results of sustainability and CE assessments for various systems (e.g., Li et al. Reference Li, Tarpani, Stamford and Gallego-Schmid2023) and have shown complementarity between the two (e.g., Khadim et al. Reference Khadim, Agliata, Thaheem and Mollo2023). Sustainability and CE concepts have in fact similarities and differences, but ultimately, they both foster peculiar objectives. In this regard, Saidani et al. (Reference Saidani, Cluzel, Leroy, Pigosso, Kravchenko and Kim2022) specifically clarified the difference among CE, life cycle assessment (LCA) and sustainability indicators. In some authors’ view, circularity indicators are part of environmental performance systems (Rigamonti & Mancini Reference Rigamonti and Mancini2021) and, as such, deserve specific attention.

As materials are a primary concern in CE (e.g., Hallstedt et al. Reference Hallstedt, Isaksson, Nylander, Andersson and Knuts2023), designers have to identify, among the others, the most suitable combination of materials in terms of performance, costs and sustainability (Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni, Orzes, Gerbino, Lanzotti, Martorelli, Mirálbes Buil, Rizzi and Roucoules2023). This optimal combination is still challenging, especially in the building industry. Here, it is exceedingly difficult to anticipate the impact of design choices and strategies on sustainability and compliance with CE principles (Eberhardt, Birkved & Birgisdottir Reference Eberhardt, Birkved and Birgisdottir2022). The correct use and experimentation of new materials are fundamental actions to move towards sustainable development (Arrigoni et al. Reference Arrigoni, Pelosato, Melià, Ruggieri, Sabbadini and Dotelli2017) in consideration of the substantial footprint otherwise caused by traditional construction materials, still in high demand (Hossain et al. Reference Hossain, Ng, Antwi-Afari and Amor2020). These new materials, mostly of natural origin, intrinsically foster the implementation of CE by improving the performance and end-of-life possibilities of the products and buildings they are part of (Barth & Carus Reference Barth and Carus2015). Particularly diffused are natural materials such as hemp or wood, which are supposed to have no negative effect on the performance of the designed products (Galimshina et al. Reference Galimshina, Moustapha, Hollberg, Padey, Lasvaux, Sudret and Habert2022). To test the environmental quality of these materials and other innovative building techniques, a common approach is to analyze buildings and houses through LCA (Arrigoni et al. Reference Arrigoni, Pelosato, Melià, Ruggieri, Sabbadini and Dotelli2017; Cabeza et al. Reference Cabeza, Rincón, Vilariño, Pérez and Castell2014; Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni, Orzes, Gerbino, Lanzotti, Martorelli, Mirálbes Buil, Rizzi and Roucoules2023). While the application of LCA follows a nearly standardized procedure, the same cannot be stated for the assessment of the compliance of products with CE principles, as better stressed in the following section. It is also worth highlighting that while the concepts of CE and sustainability share many objectives, differences are likewise acknowledged (Castro et al. Reference Castro, Trevisan, Pigosso and Mascarenhas2022; Cardoso Chrispim, Mattsson & Ulvenblad Reference Cardoso Chrispim, Mattsson and Ulvenblad2023), and, consequently, the assessment of both is useful in many instances. This kind of assessments, along with the terms used to assess CE, are particularly important when it comes to design, whether buildings only or products in general are dealt with. On the one hand, the mentioned difficulties of predicting performances, including environmental ones, in the early design stages are known with clear implications on decision-making (Borgianni, Cascini & Rotini Reference Borgianni, Cascini and Rotini2018; Parolin, McAloone & Pigosso Reference Parolin, McAloone and Pigosso2023). Markedly, the research aimed to include CE considerations in the early design phases is still immature (Pozo Arcos et al. Reference Pozo Arcos, Balkenende, Bakker and Sundin2018). This calls into question the need to perform accurate assessments once the definition of the product characteristics has moved forward during the design process. On the other hand, CE indicators used for assessment tasks are closely linked to design for circularity (Saidani et al. Reference Saidani, Kim, Cluzel, Leroy and Yannou2020); otherwise said, the acknowledgment and understanding of CE metrics can nurture design practices oriented to cope with CE overall.

This article deals with the variability of the assessment of CE using different established methods, and a case study from the building sector is used to evaluate such variability. In line with the lack of CE assessment standardization, which will be highlighted in Section 2, the objective of this article is to study the convergence of existing CE assessment methods and tools in providing consistent circularity performances. It is worth noting that, while much research agrees on the lack of standardization of CE assessment, its practical consequences for decision-making and design are poorly investigated. This work focuses on the product level of CE by comparing the results obtained with different tools for the same case study. In this way, it is possible to get insights into the practical similarities and differences of the main existing tools.

2. Background about the lack of standardization in circularity assessment

Circularity is a term typically used to denote the overall compliance of systems with the principles and goals of CE (Corona et al. Reference Corona, Shen, Reike, Carreón and Worrell2019; Harris, Martin & Diener Reference Harris, Martin and Diener2021; Al-Obaidy, Courard & Attia Reference Al-Obaidy, Courard and Attia2022). Many methods and tools to evaluate circularity exist. The main objective in assessing the circularity of products is to help decision-making by providing some information about them and about their life stages (Bragança, Mateus & Koukkari Reference Bragança, Mateus and Koukkari2010). Furthermore, the evaluation must be coherent, complete and objective (Mesa, Esparragoza & Maury Reference Mesa, Esparragoza and Maury2018). There are no standard methods or tools to assess CE in products (European Environment Agency (EEA) 2016), but the need for standardization is strong as witnessed by standardization efforts. In this respect, the standard ISO 59020, intended to assess circularity performances, is under development. It is also worth mentioning that some of the CE objectives are considered in sustainability-related standards too (Ahlstedt & Sundin Reference Ahlstedt and Sundin2023; EN4555X). Despite commonalities, there are not fully established practices for circularity assessment. However, there are several methods with this purpose, for example, the ones mentioned in Cardoso Chrispim et al. (Reference Cardoso Chrispim, Mattsson and Ulvenblad2023), Ruiz-Pastor et al. (Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni and Orzes2022), Parchomenko et al. (Reference Parchomenko, Nelen, Gillabel and Rechberger2019), Saidani et al. (Reference Saidani, Yannou, Leroy, Cluzel and Kendall2019), and Bovea and Pérez-Belis (Reference Bovea and Pérez-Belis2012). Cardoso Chrispim et al. (Reference Cardoso Chrispim, Mattsson and Ulvenblad2023) also define in their work the terms metric, tool and indicator. These definitions are adopted in this work.

CE assessment has been classified in the literature into four main groups based on the level of application of the assessment. According to Yuan, Bi & Moriguichi (Reference Yuan, Bi and Moriguichi2006), these four levels are macro-level (cities and regions), meso-level (industries and industrial symbiosis), micro-level (companies) and nano-level (products). This subdivision is acknowledged in the literature dedicated to CE assessment (e.g., de Oliveira, Dantas & Soares Reference de Oliveira, Dantas and Soares2021; Khadim et al. Reference Khadim, Agliata, Marino, Thaheem and Mollo2022), and in the mentioned ISO 59020 standard, whose applicability is expected to range “from regional, inter-organizational, organizational to the product level.” Because of the attention paid to products and design, this work focuses on the nano-level of CE assessment, which has been recognized as relevant and introduced with this specific terminology also in the design field (Saidani et al. Reference Saidani, Yannou, Leroy and Cluzel2017b).

To understand the fragmentation, complexity, extent and degree of convergence across different proposals in the field of CE assessment, the authors explored the literature to retrieve two main categories of contributions:

  1. 1. works in which a case study is assessed with multiple methods, at any level of circularity and

  2. 2. works specifically targeting circularity assessment at the nano-level.

Among the former, it is possible to find different overviews and analyses of CE measurement (Niero & Kalbar Reference Niero and Kalbar2019; Ruiz-Pastor et al. Reference Ruiz-Pastor, Mulet, Chulvi and Royo2019; Saidani et al. Reference Saidani, Yannou, Leroy, Cluzel and Kendall2019, Reference Saidani, Kravchenko, Cluzel, Pigosso, Leroy and Kim2021). Ruiz-Pastor et al. (Reference Ruiz-Pastor, Mulet, Chulvi and Royo2019) remark the lack of a standard circularity assessment method and the gaps in this regard. Other works in the same line are Morkunaite et al. (Reference Morkunaite, Al-Naber, Petrova and Svidt2021), Lonca et al. (Reference Lonca, Lesage, Majeau-Bettez, Bernard and Margni2020) or Bressanelli et al. (Reference Bressanelli, Perona and Saccani2019). Several of these works also apply the assessment methods through different case studies (Boer et al. Reference Boer, Segarra, Fernández, Vallès, Mateu and Cabeza2020; Lonca et al. Reference Lonca, Lesage, Majeau-Bettez, Bernard and Margni2020; Minunno et al. Reference Minunno, O’Grady, Morrison and Gruner2020; Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni and Orzes2022). These studies overall converge on the lack of a standard method, which is often cited as one of the most severe limitations for CE assessment.

As for the latter, they mostly show groups of CE indicators or methods (Moraga et al. Reference Moraga, Huysveld, Mathieux, Blengini, Alaerts, Van Acker, de Meester and Dewulf2019; Niero & Kalbar Reference Niero and Kalbar2019; Kristensen & Mosgaard Reference Kristensen and Mosgaard2020; Roos Lindgreen, Salomone & Reyes Reference Roos Lindgreen, Salomone and Reyes2020; Saidani et al. Reference Saidani, Kim, Cluzel, Leroy and Yannou2020; de Oliveira et al. Reference de Oliveira, Dantas and Soares2021; Khadim et al. Reference Khadim, Agliata, Marino, Thaheem and Mollo2022; Kuzma et al. Reference Kuzma, Sehnem, Lopes de Sousa Jabbour and Campos2022). Many of them agree on the lack of standard indicators and robustness in measuring CE. Even if existing methods are a good starting point, as Khadim et al. (Reference Khadim, Agliata, Marino, Thaheem and Mollo2022) pointed out, further research is needed (Roos Lindgreen et al. Reference Roos Lindgreen, Salomone and Reyes2020).

Two works are ascribable to both categories of analyzed contributions. Jerome et al. (Reference Jerome, Helander, Ljunggren and Janssen2022) study the existing indicators and then test them with seven case studies, stressing that there is a lack of consensus regarding CE indicators. Cayzer, Griffiths & Beghetto (Reference Cayzer, Griffiths and Beghetto2017) also evaluate the existing indicators while developing a product prototype. Also in this case, the main conclusion is the lack of a common way to measure CE in products.

3. Case study and methodology

This work was developed in the context of the Tiny FOP Mob Project (see details in the Acknowledgments). Within this project, a prototype of a tiny house (Figure 1) was developed with the purpose of serving as a real-world laboratory in five locations of the Venosta Valley, Italy (Nezzi et al. Reference Nezzi, Ruiz-Pastor, Altavilla, Berni and Borgianni2022). One of the purposes of the tiny house was to bring science and society closer with an emphasis on sustainability issues. In this context, the prototype of the tiny house was designed and made with sustainable materials to the largest possible extent. More in details, the used materials were:

  • hemp bricks (load-bearing walls) (Figure 2),

  • spruce wood (frame, beams and screed),

  • larch wood (floor, false ceiling and external cladding),

  • natural mortar (bricks assembly),

  • hemp fiber and natural hydraulic lime (interior surface finishing) and

  • others (galvanized titanium for the roof and vapor barrier made of wood fiber).

Figure 1. Tiny house prototype.

Figure 2. Brick used in the tiny house prototype.

The tiny house prototype has a 25 square meters area and a weight of 12 tons.

Despite tiny houses are known to be possible icons of social movements, which largely resonates with the scopes of the mentioned project, the aspects closely concerning CE (and its corresponding assessment methods) are considered here only, that is, the environmental dimension turned to be predominant in the analyses that follow.

All the required data to assess the circularity of the tiny house were collected through semi-structured interviews with the project partners, the manufacturer and material providers of the prototype, as well as from the literature. After data were collected, the most relevant methods to assess CE in literature were selected and applied to the tiny house. The method selection was based on a literature investigation and search for nonacademic, yet established, CE assessment tools.

All the nano-level CE assessment tools identified for the scope of this study were:

  • validated or accepted in the literature,

  • clearly described or providing online tools for the assessment of circularity so to be straightforwardly applied in the present work and

  • the ones providing a specific result for circularity (either with a single variable or with the combination of few variables).

The identification of pertinent tools was supported by the recent overviews of nano-level circularity assessment methods (Ruiz-Pastor et al. Reference Ruiz-Pastor, Chulvi, Mulet and Royo2022; Cardoso Chrispim et al. Reference Cardoso Chrispim, Mattsson and Ulvenblad2023). Six tools, which are summarized in Figure 3, complied with the requirements above and they were applied to the tiny house prototype. In the next subsections, the application of the different methods is shown.

Figure 3. Selected metrics for the assessment of product-level circularity with the indication of variables and number of indicators used by each metric.

3.1 Circularity Calculator

This tool, developed by Ellen MacArthur Foundation and IDEAL&CO (2020), evaluates the circularity of a product or service through several parameters regarding all life stages. It is a web platform with different parameters to be assessed. Specifically, the parameters to introduce in the web tool are shown in Figure 4, which are presented along the data pertaining to the tiny house. The tool is acknowledged in the literature and employed in other works such as de Pascale et al. (Reference De Pascale, Arbolino, Szopik-Depczyńska, Limosani and Ioppolo2021) or Roos Lindgreen et al. (Reference Roos Lindgreen, Mondello, Salomone, Lanuzza and Saija2021).

Figure 4. Tiny house input for the Circularity Calculator tool.

The tool provides three CE-related parameters beyond circularity, namely value capture, recycled content and reuse index. The result obtained with the Circular Economy Calculator shows that the circularity of the tiny house is 40%.

3.2 Circular Economy Toolkit

The Circular Economy Toolkit (Evans & Bocken Reference Evans and Bocken2013) is a free web tool, which measures the circularity of a product or service through 33 parameters. These parameters are subdivided into seven categories:

  • design, manufacture and distribute,

  • usage (by the costumer),

  • repair/maintenance of the product,

  • reuse/redistribution of the product,

  • remanufacturing/refurbishment of product or part,

  • product as a service and

  • product recycling at the end of life.

Each of the parameters within the categories is evaluated through a slide bar with three different positions. The tool provides as a result a graph, which shows the potential improvement for each category.

In order to achieve a numerical value, the three possible positions of the slide bar have been converted to a three-point Likert scale, quantifying them as a 0, 1 or 2 points and summed up to obtain a final score (Figure 5). For the sake of convenience, ordered variables have been used as continuous ones here and whenever required. The results show that the tiny house has a circularity of 35 out of 66, being 66 the least circular. This means that the tiny house is 47% circular according to the Circular Economy Toolkit.

Figure 5. Data introduced in the Circular Economy Toolkit.

3.3 Combination of circularity, novelty and concepts

The metric developed to assess the combination of circularity, novelty and concepts was developed by Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni and Orzes2022 and designated as CN_Con. It evaluates the circularity and the novelty as a whole in product concepts. The metric covers all the parameters regarding CE that can be considered in the conceptual design stage.

The CE is calculated in two steps: the first one concerns the strategies for durability the product follows. In a second step, the evaluation regards the origin of the raw materials and the destination of the different components and materials in the end of life of the product.

In the case of the tiny house assessed, only one of the 10 strategies proposed by the tool is applied, design for social innovation (2.89 points in the tool). On the other hand, new materials are used to manufacture the prototype (0 points in the tool), but these materials are recoverable (4.3 points in the tool). Accordingly, the circularity score of the tiny house is 6.36 out of 10 points. In order to make the result comparable with the other methods, the final score has been normalized and calculated as a percentage of circularity, namely 63.6%.

3.4 Metric for quantifying product-level circularity

This metric (Linder, Sarasini & van Loon Reference Linder, Sarasini and van Loon2017) evaluates the circularity of products only in terms of cost of recirculated parts. In the equation, the scholars propose a numerical value is obtained as the ratio between the economic value of recirculated parts and the economic value of all parts.

In the case of the tiny house studied, there are no recirculated parts in the manufacturing of the product. Therefore, the circularity of the tiny house is 0% in this case.

3.5 Circular Spidermap

This tool (Van den Berg and Bakker, Reference Van den Berg and Bakker2015) evaluates circularity according to product aspects regarding its lifetime, the maintenance and the recycling. Specifically, the parameters evaluated are

  • future proof,

  • disassembly,

  • maintenance,

  • remake and

  • recycle.

The product evaluated is assigned one of four possible values for each parameter. In the case of the tiny house, the parameters have been converted to a four-point Likert scale, quantifying them as 1, 2, 3 or 4 points, being 4 the most circular. The results are shown in Figure 6.

Figure 6. Results of Circular Spidermap tool.

As in the other cases, the circularity score was calculated. In this case, a maximum score in the parameter (4) is equal to 100% circularity and the minimum score (1) is 25% circularity (the score 0 is not foreseen in this method). The final percentage of circularity is the average of all the parameters, which results in 65% for the present case study.

3.6 Circular Design Tool

When applying this tool (Moreno, Ponte & Charnley Reference Moreno, Ponte and Charnley2017), parameters about the life cycle, resource conservation and user and product development are assessed. A circularity index is calculated according to different parameters and an importance factor (provided by the tool itself). The score varies between 0 and 787.5, being the largest value the most circular. In the case of the tiny house, the score obtained after assessing all the parameters is 318.2. In Figure 7, the scores for each parameter are reported. The normalized score has been calculated by means of ratio: it is 40.41% of circularity.

Figure 7. Tiny house assessment with the Circular Design Tool.

4. Comparison results

After applying the methods, a circularity percentage for the tiny house has been obtained for each method. The final normalized scores are summarized in Figure 8 to ease comparisons.

Figure 8. Normalized circularity results.

As it is shown, in six out of the seven methods, the circularity scores range between 40 and 65%. In the case of the metric developed by Linder et al. (Reference Linder, Sarasini and van Loon2017), the circularity is clearly affected by the peculiar factors used for the assessment, which differ substantially with respect to the other tools. In Linder et al. (Reference Linder, Sarasini and van Loon2017), only costs are considered, which leads to a result of no circularity, since the other CE-related features of the tiny house prototype are neglected. As the importance of considered variables emerge here, the domains of variables dealt with in each of the employed CE assessment tools is illustrated in Figure 3. According to Figure 3, the most common variables are within materials optimization, lifetime and maintenance, each present in five methods. The least diffused variables are the ones concerning to issues arguably ascribable to CE, such as the product specifications, the novelty and the system design or users; each of these variables are used in one of the methods only. On the other hand, most of the methods consider five variables. The Circularity Calculator (15) and the Circular Economy Toolkit (33) are the methods using the most indicators. As mentioned, the metric for quantifying product-level circularity, instead, uses one indicator only.

5. Discussion

The results obtained with the assessment tools are consistent according to the main features and materials of the tiny house evaluated, since the house is built with sustainable materials but, for example, end-of-life actions were not focused on in the design of the tiny house. The results underline the need of integrating the CE concepts in all the stages of the design, manufacturing, use and end-of-life of buildings in general, and of the tiny house in particular. Thus, the fair circularity of the prototype is mostly due to its sustainable materials used for its construction, which is obviously one of its strengths. This can be seen from the results obtained in the Circularity Calculator, The Circular Economy Toolkit, the CN_Con, the Circular Spidermap and the Circular Design Tool, since all of them consider variables related to materials. To improve the overall circularity of the tiny house, a possibility would be to manufacture it with recirculated materials; this issue is stressed in the tools considering the starting materials, which are, again, all the tools except the metric for quantifying product-level circularity. In addition, a strong possible improvement would be designing the tiny house for easy disassembly and repair, in line with the CE actions considered in the Circularity Calculator, Circular Economy Toolkit, the CN_Con, the Circular Spidermap and the Circular Design Tool. This evidence supports that not only are circularity scores comparable but also that the priority actions to align with CE are substantially consistent. This can be justified by the similarity of the set of variables used to calculate circularity, as made more apparent below.

The tools applied mostly focus on the usage and maintenance of products, followed by the material quantity and the lifetime. Other variables considered are the design and manufacturing of the products, the costs, the recycling of materials or the general environmental impact. The possibility of implementing product–service features in the products is considered in two assessment methods (Evans & Bocken Reference Evans and Bocken2013; Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni and Orzes2022). Also, other aspects are considered, such as the novelty of the products (Brezet & van Hemel Reference Brezet and van Hemel1997; Ruiz-Pastor et al. Reference Ruiz-Pastor, Altavilla, Nezzi, Borgianni and Orzes2022). This can contribute to evaluate in a more comprehensive way products and concepts, since novelty and creativity are crucial to fulfill CE-related requirements (Golinska et al. Reference Golinska, Kosacka, Mierzwiak and Werner-Lewandowska2015).

Furthermore, the sustainability of the materials must be matched with the right behavior at the end of life of the buildings. There could be the need of incentivizing the users and/or dismantling companies to ensure the most sustainable products’ end of life. This issue is not only a matter of design, but it also involves educating the users and manufacturers in a sustainable use of products and materials.

6. Conclusions

In this work, six methods to assess CE were applied to a tiny house prototype. The prototype was built with sustainable materials, such as lime-based hemp bricks and wood, and with the purpose to serve as a real-world laboratory. According to the analysis, the tools exhibit differences in the way CE is assessed, but, despite that, the circularity results are quite close in most of the cases (40–65%), as they show an intermediate score for the case study. The number of variables studied by the tools varies between 1 and 5. On the other hand, the number of indicators ranges between 3 and 46. As all the tools have different features, the results achieved can be considered fairly close.

This similarity shows how the results obtained when applying the considered tools and methods can be a good indicator of product circularity performance. This type of tools can help to design more circular products from the beginning of the design process; benefits can be especially in terms of resources saving and optimization.

A limitation of the present study is that the similarity of circularity scores is observed through a case study only, and other examples could help corroborate the results. The case study was taken from the building sector, and it is therefore worth testing the convergence of CE assessment tools in more traditional product design fields. In addition, for practical reasons, the study focused on nano-level CE assessment tools that provide a well-defined circularity score or where this score can be easily extrapolated. Hence, complex nano-level assessment systems providing a large and non-independent number of variables associated with CE were not considered in this comparative study. The convergence of indications to redesign the tiny house while further aligning it with CE principles can be tested also with other assessment tools.

While the issue concerning the lack of standardization has not been overcome through the presented results, it is possible to claim that the existing CE assessment methods can be considered sufficiently reliable thanks to their convergence. Hence, users can consider the results obtained through most of the studied methods as a good proxy of the circular performance of what is being designed and developed. In practical terms, this alleviates the problem of choosing the “right” or “best” nano-level CE assessment tool. In turn, as the closeness between CE indicators and rules for eco-design has been highlighted in the first section, it can be inferred that the consideration of any of the examined CE assessment tools can be useful for the generation of better designs. However, the claimed methodological shortcomings concerning the introduction of CE principles in early design stages remain an open issue. The results of this work suggest that the understanding of nano-level CE assessment methods can be a starting point here. A point to be evaluated is the applicability of CE assessment tools to different products, whose investigation is part of the authors’ planned future work. In addition, the authors intend to systematically review CE indicators at the nano-level, so to develop a checklist of CE aspects to be considered in product design. This work can benefit from the results recently presented by de Oliveira and Oliveira (Reference de Oliveira and Oliveira2023) and, methodologically, from past experiences where indicators at different CE levels have been selected and aggregated (e.g., Sacco et al. Reference Sacco, Vinante, Borgianni and Orzes2021). While designers aim for comprehensiveness when they operate, a clear, inclusive, and context-dependent taxonomy of product-level CE indicators can represent a major step forward in designing for the CE. This is to be favorably integrated, nevertheless, by tools supporting designers in the consideration of sustainability aspects that are not included in the concept of CE. It has to be remarked that CE and sustainability show substantial differences beyond the many affinities (Delaney et al. Reference Delaney, Liu, Zhu, Xu and Dai2022), notably when it comes to approaching design (Cao et al. Reference Cao, Hsu and Lu2024). By building upon (e.g., Saidani et al. Reference Saidani, Cluzel, Leroy, Pigosso, Kravchenko and Kim2022), complementary indicators originating from the fields of sustainable development and design could be used here to ensure that an enhanced circularity leads to sustainable benefits.

Acknowledgments

The study has been conducted in the context of the project “Tiny FOP MOB – A Real World Laboratory made of wood and hemp travelling through the Vintschgau Valley.”

Financial support

This study is supported by the European Regional Development Fund (ERDF) Investment for Growth and Jobs Program 2014–2020, 5th call in the Axis 1 “Research and Innovation” of the Autonomous Province of Bolzano – South Tyrol, grant FESR1161. Dr Laura Ruiz-Pastor was supported by the Margarita Salas postdoctoral contract MGS/2021/29 (UP2021-021) financed by the European Union – NextGenerationEU. This work was supported by the Open Access Publishing Fund of the Free University of Bozen-Bolzano.

References

Ahlstedt, E. & Sundin, E. 2023 Assessing product suitability for remanufacturing – A case study of a handheld battery-driven assembly tool. Procedia CIRP 116, 582587.CrossRefGoogle Scholar
Al-Obaidy, M., Courard, L. & Attia, S. 2022 A parametric approach to optimizing building construction systems and carbon footprint: A case study inspired by circularity principles. Sustainability 14 (6), 3370.CrossRefGoogle Scholar
Arrigoni, A., Pelosato, R., Melià, P., Ruggieri, G., Sabbadini, S. & Dotelli, G. 2017 Life cycle assessment of natural building materials: The role of carbonation, mixture components and transport in the environmental impacts of hempcrete blocks. Journal of Cleaner Production 149, 10511061.CrossRefGoogle Scholar
Azapagic, A. & Perdan, S. 2000 Indicators of sustainable development for industry: A general framework. Process Safety and Environmental Protection 78 (4), 243261.CrossRefGoogle Scholar
Barth, M. & Carus, M. 2015 Carbon Footprint and Sustainability of Different Natural Fibres for Biocomposites and Insulation Material. Nova-Institute. http://eiha.org/media/2017/01/15–04-Carbon-Footprint-of-Natural-Fibres-nova1.pdf.Google Scholar
Bhamra, T. & Hernandez, R. J. 2021 Thirty years of design for sustainability: An evolution of research, policy and practice. Design Science 7, e2.CrossRefGoogle Scholar
Bocken, N. M., Olivetti, E. A., Cullen, J. M., Potting, J. & Lifset, R. 2017 Taking the circularity to the next level: A special issue on the circular economy. Journal of Industrial Ecology 21 (3), 476482.CrossRefGoogle Scholar
Boer, D., Segarra, M., Fernández, A. I., Vallès, M., Mateu, C. & Cabeza, L. F. 2020 Approach for the analysis of TES technologies aiming towards a circular economy: Case study of building-like cubicles. Renewable Energy 150, 589597.CrossRefGoogle Scholar
Borgianni, Y., Cascini, G. & Rotini, F. 2018 Investigating the future of the fuzzy front end: Towards a change of paradigm in the very early design phases? Journal of Engineering Design 29 (11), 644664.CrossRefGoogle Scholar
Bovea, M. D. & Pérez-Belis, V. 2012 A taxonomy of ecodesign tools for integrating environmental requirements into the product design process. Journal of Cleaner Production 20 (1), 6171.CrossRefGoogle Scholar
Bragança, L., Mateus, R. & Koukkari, H. 2010 Building sustainability assessment. Sustainability 2 (7), 20102023.CrossRefGoogle Scholar
Bressanelli, G., Perona, M. & Saccani, N. 2019 Challenges in supply chain redesign for the circular economy: A literature review and a multiple case study. International Journal of Production Research 57 (23), 73957422.CrossRefGoogle Scholar
Brezet, H. & van Hemel, C. 1997 Ecodesign-A Promising Approach to Sustainable Production and Consumption. United Nations Environmental Programme (UNEP).Google Scholar
Buchanan, R. 2001 Human dignity and human rights: Thoughts on the principles of human-centered design. Design Issues 17 (3), 3539.CrossRefGoogle Scholar
Cabeza, L. F., Rincón, L., Vilariño, V., Pérez, G. & Castell, A. 2014 Life cycle assessment (LCA) and life cycle energy analysis (LCEA) of buildings and the building sector: A review. Renewable and Sustainable Energy Reviews 29, 394416.CrossRefGoogle Scholar
Cao, X., Hsu, Y. & Lu, H. 2024 Design heuristics cards for circular economy to support generating ideas. The Design Journal 27, 111132.CrossRefGoogle Scholar
Cardoso Chrispim, M., Mattsson, M. & Ulvenblad, P. 2023 The underrepresented key elements of circular economy: A critical review of assessment tools and a guide for action. Sustainable Production and Consumption 35, 539558.CrossRefGoogle Scholar
Castro, C. G., Trevisan, A. H., Pigosso, D. A. & Mascarenhas, J. 2022 The rebound effect of circular economy: Definitions, mechanisms and a research agenda. Journal of Cleaner Production 345, 131136.CrossRefGoogle Scholar
Cayzer, S., Griffiths, P. & Beghetto, V. 2017 Design of indicators for measuring product performance in the circular economy. International Journal of Sustainable Engineering 10 (4–5), 289298.CrossRefGoogle Scholar
Corona, B., Shen, L., Reike, D., Carreón, J. R. & Worrell, E. 2019 Towards sustainable development through the circular economy—A review and critical assessment on current circularity metrics. Resources, Conservation and Recycling 151, 104498.CrossRefGoogle Scholar
Cottafava, D. & Ritzen, M. 2021 Circularity indicator for residential buildings: Addressing the gap between embodied impacts and design aspects. Resources, Conservation and Recycling 164, 105120.CrossRefGoogle Scholar
de Oliveira, C. T., Dantas, T. E. T. & Soares, S. R. 2021 Nano and micro level circular economy indicators: Assisting decision-makers in circularity assessments. Sustainable Production and Consumption 26, 455468.CrossRefGoogle Scholar
de Oliveira, C. T. & Oliveira, G. G. A. 2023 What circular economy indicators really measure? An overview of circular economy principles and sustainable development goals. Resources, Conservation and Recycling 190, 106850.CrossRefGoogle Scholar
De Pascale, A., Arbolino, R., Szopik-Depczyńska, K., Limosani, M. & Ioppolo, G. 2021 A systematic review for measuring circular economy: The 61 indicators. Journal of Cleaner Production 281, 124942.CrossRefGoogle Scholar
Delaney, E., Liu, W., Zhu, Z., Xu, Y. & Dai, J. S. 2022 The investigation of environmental sustainability within product design: A critical review. Design Science 8, e15.CrossRefGoogle Scholar
den Hollander, M. C., Bakker, C. A. & Hultink, E. J. 2017 Product design in a circular economy: Development of a typology of key concepts and terms. Journal of Industrial Ecology 21 (3), 517525.CrossRefGoogle Scholar
Dokter, G., Thuvander, L. & Rahe, U. 2021 How circular is current design practice? Investigating perspectives across industrial design and architecture in the transition towards a circular economy. Sustainable Production and Consumption 26, 692708.CrossRefGoogle Scholar
Eberhardt, L. C. M., Birkved, M. & Birgisdottir, H. 2022 Building design and construction strategies for a circular economy. Architectural Engineering and Design Management 18 (2), 93113.CrossRefGoogle Scholar
EN4555X series. 2020 CEN-CENELEC. Paris, France: AFNOR.Google Scholar
European Environment Agency (EEA). 2016 More from Less—Material Resource Efficiency in Europe. Copenhagen, Denmark.Google Scholar
Evans, J. & Bocken, N. 2013 Circular Economy Toolkit. Cambridge Institute for Manufacturing. http://circulareconomytoolkit.org.Google Scholar
Galimshina, A., Moustapha, M., Hollberg, A., Padey, P., Lasvaux, S., Sudret, B. & Habert, G. 2022 Bio-based materials as a robust solution for building renovation: A case study. Applied Energy 316, 119102.CrossRefGoogle Scholar
Golinska, P., Kosacka, M., Mierzwiak, R. & Werner-Lewandowska, K. 2015 Grey decision making as a tool for the classification of the sustainability level of remanufacturing companies. Journal of Cleaner Production 105, 2840.CrossRefGoogle Scholar
Hallstedt, S. I., Isaksson, O., Nylander, J. W., Andersson, P. & Knuts, S. 2023 Sustainable product development in aeroengine manufacturing: Challenges, opportunities and experiences from GKN aerospace engine system. Design Science 9, e22.CrossRefGoogle Scholar
Harris, S., Martin, M. & Diener, D. 2021 Circularity for circularity’s sake? Scoping review of assessment methods for environmental performance in the circular economy. Sustainable Production and Consumption 26, 172186.CrossRefGoogle Scholar
Hossain, M. U., Ng, S. T., Antwi-Afari, P. & Amor, B. 2020 Circular economy and the construction industry: Existing trends, challenges and prospective framework for sustainable construction. Renewable and Sustainable Energy Reviews 130, 109948.CrossRefGoogle Scholar
IDEAL&CO, E. 2020 The Circularity Calculator. Software available via www.circularitycalculator.com.Google Scholar
Jerome, A., Helander, H., Ljunggren, M. & Janssen, M. 2022 Mapping and testing circular economy product-level indicators: A critical review. Resources, Conservation and Recycling 178, 106080.CrossRefGoogle Scholar
Kefayati, Z. & Moztarzadeh, H. 2015 Developing effective social sustainability indicators in architecture. Bulletin of Environment, Pharmacology and Life Sciences 4, 4056.Google Scholar
Khadim, N., Agliata, R., Marino, A., Thaheem, M. J. & Mollo, L. 2022 Critical review of nano and micro-level building circularity indicators and frameworks. Journal of Cleaner Production 357, 131859.CrossRefGoogle Scholar
Khadim, N., Agliata, R., Thaheem, M. J. & Mollo, L. 2023 Whole building circularity indicator: A circular economy assessment framework for promoting circularity and sustainability in buildings and construction. Building and Environment 241, 110498.CrossRefGoogle Scholar
Kim, H., Cluzel, F., Leroy, Y., Yannou, B. & Yannou-Le Bris, G. 2020 Research perspectives in ecodesign Design Science 6, e7.CrossRefGoogle Scholar
Kristensen, H. S. & Mosgaard, M. A. 2020 A review of micro level indicators for a circular economy–moving away from the three dimensions of sustainability? Journal of Cleaner Production 243, 118531.CrossRefGoogle Scholar
Kuzma, E. L., Sehnem, S., Lopes de Sousa Jabbour, A. B. & Campos, L. M. 2022 Circular economy indicators and levels of innovation: An innovative systematic literature review. International Journal of Productivity and Performance Management 71 (3), 952980.CrossRefGoogle Scholar
Li, J., Tarpani, R. R. Z., Stamford, L. & Gallego-Schmid, A. 2023 Life cycle sustainability assessment and circularity of geothermal power plants. Sustainable Production and Consumption 35, 141156.CrossRefGoogle Scholar
Linder, M., Sarasini, S. & van Loon, P. 2017 A metric for quantifying product‐level circularity. Journal of Industrial Ecology 21 (3), 545558.CrossRefGoogle Scholar
Lonca, G., Lesage, P., Majeau-Bettez, G., Bernard, S. & Margni, M. 2020 Assessing scaling effects of circular economy strategies: A case study on plastic bottle closed-loop recycling in the USA PET market. Resources, Conservation and Recycling 162, 105013.CrossRefGoogle Scholar
Mesa, J., Esparragoza, I. & Maury, H. 2018 Developing a set of sustainability indicators for product families based on the circular economy model. Journal of Cleaner Production 196, 14291442.CrossRefGoogle Scholar
Mesa, J. A. 2023 Design for circularity and durability: an integrated approach from DFX guidelines. Research in Engineering Design 34, 443460.CrossRefGoogle Scholar
Minunno, R., O’Grady, T., Morrison, G. M. & Gruner, R. L. 2020 Exploring environmental benefits of reuse and recycle practices: A circular economy case study of a modular building. Resources, Conservation and Recycling 160, 104855.CrossRefGoogle Scholar
Moraga, G., Huysveld, S., Mathieux, F., Blengini, G. A., Alaerts, L., Van Acker, K., de Meester, S. & Dewulf, J. 2019 Circular economy indicators: What do they measure? Resources, Conservation and Recycling 146, 452461.CrossRefGoogle ScholarPubMed
Moreno, M. A., Ponte, O. & Charnley, F. 2017 Taxonomy of design strategies for a circular design tool. In PLATE: Product Lifetimes and the Environment, pp. 275279. IOS Press.Google Scholar
Morkunaite, L., Al-Naber, F. H., Petrova, E. & Svidt, K. 2021 An open data platform for early-stage building circularity assessment. In Proceedings of the 38th International Conference of CIB W78, pp. 813822. University of Ljubljana.Google Scholar
Muñoz, S., Hosseini, M. R. & Crawford, R. H. 2024 Towards a holistic assessment of circular economy strategies: The 9R circularity index. Sustainable Production and Consumption 47, 400412.CrossRefGoogle Scholar
Nezzi, C., Ruiz-Pastor, L., Altavilla, S., Berni, A. & Borgianni, Y. 2022 How sustainability-related information affects the evaluation of designs: A case study of a locally manufactured mobile tiny house. Designs 6 (3), 57.CrossRefGoogle Scholar
Niero, M. & Kalbar, P. P. 2019 Coupling material circularity indicators and life cycle based indicators: A proposal to advance the assessment of circular economy strategies at the product level. Resources, Conservation and Recycling 140, 305312.CrossRefGoogle Scholar
Parchomenko, A., Nelen, D., Gillabel, J. & Rechberger, H. 2019 Measuring the circular economy-a multiple correspondence analysis of 63 metrics. Journal of Cleaner Production 210, 200216.CrossRefGoogle Scholar
Parolin, G., McAloone, T. C. & Pigosso, D. C. 2023 The effects of scenarios on decision-making quality in early design–an empirical study. Proceedings of the Design Society 3, 33753384.CrossRefGoogle Scholar
Pozo Arcos, B., Balkenende, A. R., Bakker, C. A. & Sundin, E. 2018 Product design for a circular economy: Functional recovery on focus. In DS 92: Proceedings of the DESIGN 2018 15th International Design Conference, The Design Society. pp. 27272738.CrossRefGoogle Scholar
Rigamonti, L. & Mancini, E. 2021 Life cycle assessment and circularity indicators. International Journal of Life Cycle Assessment 26, 19371942.CrossRefGoogle Scholar
Roos Lindgreen, E., Mondello, G., Salomone, R., Lanuzza, F. & Saija, G. 2021 Exploring the effectiveness of grey literature indicators and life cycle assessment in assessing circular economy at the micro level: A comparative analysis. International Journal of Life Cycle Assessment 26, 21712191.CrossRefGoogle Scholar
Roos Lindgreen, E., Salomone, R. & Reyes, T. 2020 A critical review of academic approaches, methods and tools to assess circular economy at the micro level. Sustainability 12 (12), 4973.CrossRefGoogle Scholar
Ruiz-Pastor, L., Altavilla, S., Nezzi, C., Borgianni, Y. & Orzes, G. 2022 Life cycle assessment of a mobile tiny house made with sustainable materials and design implications. In Advances on Mechanics, Design Engineering and Manufacturing IV: Proceedings of the International Joint Conference on Mechanics, Design Engineering & Advanced Manufacturing, JCM 2022, pp. 2838. Springer International Publishing.Google Scholar
Ruiz-Pastor, L., Chulvi, V., Mulet, E. & Royo, M. 2022 A metric for evaluating novelty and circularity as a whole in conceptual design proposals. Journal of Cleaner Production 337, 130495.CrossRefGoogle Scholar
Ruiz-Pastor, L., Mulet, E., Chulvi, V. & Royo, M. 2019 Analysis of the circularity metrics applicability in the conceptual product design stage. In 23rd International Congress on Project Management and Engineering, International Project Management Association (IPMA). pp. 1012.Google Scholar
Ruiz-Pastor, L., Altavilla, S., Nezzi, C., Borgianni, Y. & Orzes, G. (2023). Life Cycle Assessment of a Mobile Tiny House Made with Sustainable Materials and Design Implications. In: Gerbino, S., Lanzotti, A., Martorelli, M., Mirálbes Buil, R., Rizzi, C. & Roucoules, L. (eds) Advances on Mechanics, Design Engineering and Manufacturing IV. JCM 2022. Lecture Notes in Mechanical Engineering. Cham: Springer. https://doi.org/10.1007/978-3-031-15928-2_3.Google Scholar
Sacco, P., Vinante, C., Borgianni, Y. & Orzes, G. 2021 Circular economy at the firm level: A new tool for assessing maturity and circularity. Sustainability 13 (9), 5288.CrossRefGoogle Scholar
Saidani, M., Cluzel, F., Leroy, Y., Pigosso, D., Kravchenko, M. & Kim, H. 2022 Nexus between life cycle assessment, circularity and sustainability indicators—Part II: Experimentations. Circular Economy and Sustainability 2 (4), 13991424.CrossRefGoogle Scholar
Saidani, M., Kim, H., Cluzel, F., Leroy, Y. & Yannou, B. 2020 Product circularity indicators: What contributions in designing for a circular economy?. In Proceedings of the Design Society: DESIGN Conference (Vol. 1, pp. 21292138). Cambridge University Press.Google Scholar
Saidani, M., Kravchenko, M., Cluzel, F., Pigosso, D., Leroy, Y. & Kim, H. 2021 Comparing life cycle impact assessment, circularity and sustainability indicators for sustainable design: Results from a hands-on project with 87 engineering students. Proceedings of the Design Society 1, 681690.CrossRefGoogle Scholar
Saidani, M., Yannou, B., Leroy, Y. & Cluzel, F. 2017a How to assess product performance in the circular economy? Proposed requirements for the design of a circularity measurement framework. Recycling 2 (1), 6.CrossRefGoogle Scholar
Saidani, M., Yannou, B., Leroy, Y. & Cluzel, F. 2017b Hybrid top-down and bottom-up framework to measure products’ circularity performance. In International Conference on Engineering Design, ICED 17, pp. 8190. The University of British Columbia.Google Scholar
Saidani, M., Yannou, B., Leroy, Y., Cluzel, F. & Kendall, A. 2019 A taxonomy of circular economy indicators. Journal of Cleaner Production 207, 542559.CrossRefGoogle Scholar
Stölzle, M. G., Roth, D. & Kreimeyer, M. 2023 Classification of methodologies for design for circular economy based on a literature study. Proceedings of the Design Society 3, 927936.CrossRefGoogle Scholar
Sumter, D., de Koning, J., Bakker, C. & Balkenende, R. 2020 Circular economy competencies for design. Sustainability 12 (4), 1561.CrossRefGoogle Scholar
Valenzuela-Venegas, G., Salgado, J. C. & Díaz-Alvarado, F. A. 2016 Sustainability indicators for the assessment of eco-industrial parks: Classification and criteria for selection. Journal of Cleaner Production 133, 99116.CrossRefGoogle Scholar
Van den Berg, M. R. & Bakker, C. A. 2015 A product design framework for a circular economy. In Proceedings of the PLATE Conference, pp. 365379. Nottingham Trent University: CADBE.Google Scholar
Vinante, C., Sacco, P., Orzes, G. & Borgianni, Y. 2021 Circular economy metrics: Literature review and company-level classification framework. Journal of Cleaner Production 288, 125090.CrossRefGoogle Scholar
Yuan, Z., Bi, J. & Moriguichi, Y. 2006 The circular economy: A new development strategy in China. Journal of Industrial Ecology 10 (1–2), 48.CrossRefGoogle Scholar
Figure 0

Figure 1. Tiny house prototype.

Figure 1

Figure 2. Brick used in the tiny house prototype.

Figure 2

Figure 3. Selected metrics for the assessment of product-level circularity with the indication of variables and number of indicators used by each metric.

Figure 3

Figure 4. Tiny house input for the Circularity Calculator tool.

Figure 4

Figure 5. Data introduced in the Circular Economy Toolkit.

Figure 5

Figure 6. Results of Circular Spidermap tool.

Figure 6

Figure 7. Tiny house assessment with the Circular Design Tool.

Figure 7

Figure 8. Normalized circularity results.