Version: 24.03

Adoption View

Circularity KIT

Vision & Mission

Introduction

The Circularity KIT shall empower stakeholders to transition towards a circular economy by providing frameworks, guidelines and best practices to enhance sustainability credentials, enable data-driven decision-making and foster collaboration and innovation in the automotive industry.

Secondary material content, material accounting, dismantling services, the CE-Assistant, and the secondary marketplace are the five focus topics that form the Circularity KIT as of now. The offered content and artifacts address important use cases such as sustainable materials management, waste minimization and resource efficiency, that contribute to more sustainable and circular automotive value loops.

The overarching goals of the Circularity KIT, therefore, are to:

Establish an understanding of requirements along circular value chains and how businesses can profit by implementing sustainable solutions.
Offer standards and guidelines for industry stakeholders.
Explain different circularity topics and provide tools to implement them.

Vision

Vision Catch Phrase: "Closing the Loop, by harnessing the power of Circularity"

Context: Our vision is to create a future where resources are intelligently and efficiently utilized, enabling industries and communities to minimize waste, embrace R-strategies, and foster a circular economy that leads to a sustainable and prosperous world.

The Circularity KIT serves as a practical set of tools, guidelines, and best practices designed to help stakeholders in the automotive industry to transition towards this vision.

Mission

In a world facing increasing environmental pressures and resource scarcity, transitioning to a circular economy is crucial. This approach ensures responsible resource management through R-strategies, secondary material quotas, material accounting, and optimized end-of-life processes. By closing the loop on material flows, we can reduce our environmental impact, drive innovation, and create economic opportunities that secure a sustainable future.

The KIT entails a description of the overall business value, use case context, an introduction to the subtopics secondary material content, material accounting, dismantling services, CE-Assistant as well as a circularity glossary and is complemented by user journeys, business processes, calculation frameworks, interoperable data models and standards needed to adopt the Catena-X circularity focus topics.

All described specifications in the KIT are based on Catena-X standards like Asset Administration Shell, SSI and a decentral Digital Twin Registry. They refer to other Catena-X KITs like the Traceability KIT to ensure interoperability and data sovereignty according to IDSA and Gaia-X principles.

Business Context

The Circularity KIT provides business opportunities for service providers in various ways:

Unified Circular Economy Framework: Service providers can leverage a comprehensive and standardized framework for implementing circular economy principles in the automotive industry. This unified approach simplifies integration and collaboration with other stakeholders, reducing investment costs and accelerating the development and deployment of innovative solutions.
Access to New Market Opportunities: The KIT enables service providers to tap into emerging market opportunities driven by the increasing demand for sustainable solutions. By offering tailored services on the Catena-X marketplace, service providers can scale their customer base, expand their reach, and unlock new revenue streams.
Enhanced Sustainability Credentials: By aligning with the principles of the Circularity KIT, service providers can demonstrate their commitment to sustainability and strengthen their reputation in the market. This commitment can lead to increased customer trust, better brand positioning, and a competitive advantage in the Catena-X network.
Data-Driven Decision Making: The Circularity KIT promotes data-driven decision making by offering access to material accounting data and insights into end-of-life processes within the automotive industry. Service providers can use this data to develop targeted solutions, optimize their offerings, and drive continuous improvement in their services.
Collaboration and Innovation: By using the Circularity KIT, service providers can actively participate in a network of automotive industry stakeholders committed to fostering a circular economy. This collaborative environment enables the exchange of ideas, knowledge, and best practices, driving innovation and enhancing the overall value of solutions offered in the Catena-X marketplace.

Circularity KIT Wheel

In its first version the KIT covers 5 focus topics along an automotive value loop.

Secondary Material Content: promotes the use of secondary materials in the automotive industry by providing a standardized data model for data exchange and a calculation framework.
Material Accounting: provides standardized scrap/waste and secondary material data exchange for the ecosystem partners to create transparency about recycling activities and verifiable closed loops.
EoL / Dismantling Services: offers essential support for the digitalization and automation of the EoL phase to consequently close value loops.
CE-Assistant (Circular Strategy Assistant): is a decision support system that facilitates the selection of the optimal R-Strategy for end-of-life vehicles, with a focus on Reuse, Remanufacturing, Recycling, and Recovery, guided by a comprehensive technical and environmental assessment process.
Secondary Marketplace: buying and selling used components and secondary raw materials in order to create and open new opportunities for collaborating across the value chain and closing the loop on component and material level.

Figure 1

Circularity KIT Wheel

Use Case / Domain Explanation

Status Quo / Today's challenge: The automotive industry is one of the largest consumers of raw materials, including metals, plastics, and textiles. Managing these materials sustainably and efficiently is a significant challenge, with an increasing focus on reducing waste, improving recyclability, and ensuring responsible sourcing. Traditional linear models of material consumption led to resource depletion, environmental degradation, and missed economic opportunities.

Values for taking the challenge: By adopting the Circularity KIT and embracing circular economy principles, automotive companies can transition to sustainable materials management, improve resource efficiency, and contribute to a greener, more resilient industry.

Benefits for OEMs, SMEs, and Solution Providers:

OEMs and large suppliers:
- Minimize raw material consumption and waste generation by integrating R-strategies and secondary material quotas in their production processes.
- Enhance their brand image and reputation by adopting eco-friendly practices and demonstrating commitment to sustainability.
- Achieve regulatory compliance and meet customer expectations for environmentally responsible products.
SMEs can:
- Access cost-effective, high-quality secondary materials for their production processes, reducing dependency on non-renewable resources.
- Improve competitiveness by adopting innovative circular economy technologies and practices.
- Collaborate with other industry stakeholders to develop and implement sustainable solutions.
Solution Providers can:
- Develop and market innovative technologies, products, and services that support circular economy principles in the automotive industry.
- Access new market opportunities and scale their customer base through a circularity network and shared services.
- Leverage the collective wisdom of industry stakeholders to drive continuous improvement and innovation.

Material Accounting

Introduction

Material Accounting: Enabling Transparency in the Circular Economy to Validate Material Loops

In the dynamic landscape of modern industry, the pursuit of a circular economy has become increasingly vital. This transformative approach seeks to minimize waste and enhance resource efficiency by promoting the reuse, recycling and repurposing of materials throughout their entire lifecycle. However, the realization of a truly circular economy faces significant challenges, primarily stemming from the absence of standardized data exchange and communication among the diverse network of stakeholders involved in the process.

Currently, there is a notable absence of a uniform data format or exchange mechanism for recycled materials within industrial processes and value chains. This lack of transparency presents a barrier to comprehending the flow of materials and recycled materials circulating within this ecosystem. Without a standardized approach, tracking the contributions of recycled materials, assessing their successful reintegration into the circular loop, and quantifying output volumes remain challenging tasks.

The circular economy involves a complex interplay of various stakeholders, ranging from tier-n companies to original equipment manufacturers (OEMs), each employing unique methods for measuring inputs and outputs. The overarching objective of the material accounting feature in the Circularity KIT, therefore, is to make the circular economy visible and digitally verifiable across the automotive value chain.

To realize this ambition, a standardized framework is imperative, one that facilitates the exchange of material data for both primary and secondary raw materials, including corresponding quantities and qualities, illuminating material flows across the entire value chain.

The image below shows the big picture of a circular economy when material is tracked over its complete life cycle excluding the usage phase.

Figure 2

Overview Material flow

Business Value

From a business perspective, the material accounting KIT is characterized by the following attributes:

Standardized Data Exchange: Facilitation of standardized data exchange regarding scrap, waste, and secondary materials among ecosystem partners.
Verifiable Closed Loops: The KIT enables the establishment of verifiable closed loops for material tracking.
Increased Material Recycling: The KIT promotes the recycling of materials within the same industry, increasing sustainability.
Transparency: It provides higher transparency regarding the availability of secondary materials.

Use Case / Domain

Material Accounting in Catena-X

Catena-X offers a decentral, sovereign, cross-organizational data exchange. For Material Accounting the following scenario could be addressed: Registering secondary materials as decentral digital twins in the Catena-X network based on material batches.

The goal of the Material Accounting Feature inside the Catena-X consortium and association is to collaborate on exchanging standardized secondary material information across the upstream & downstream value in order to develop a standardized data model. To do so, we identified potential data points along a closed loop with OEM, recycler and supplier as stakeholders as seen in the picture below. Further feature content will follow in upcoming versions of the Circularity KIT.

Figure 3

Data Points along the Value Chain

Secondary Material Content

Introduction

Introducing the Secondary Material Framework within the Circularity KIT by Catena-X: Enhancing Sustainability and Communication in the Automotive Value Chain.

In the pursuit of sustainability and resource efficiency, the automotive industry is continuously exploring innovative ways to incorporate secondary materials into its value chain. At the forefront of this endeavor is the secondary material framework, a pivotal component of Catena-X's Circularity KIT.

Designed with a clear mission, this framework seeks to revolutionize the utilization of secondary materials throughout the automotive value chain, extending its impact to tier-n companies and OEMs alike. Through a multi-faceted approach, the secondary material framework not only optimizes accessibility to secondary material information but also advances collaboration and communication among diverse stakeholders within the industry.

By facilitating seamless data exchange and introducing standardized calculation methodologies, this framework establishes a transparent foundation that harmonizes communication among stakeholders by employing consistent metrics. The decentralized nature of this data ecosystem empowers each actor to manage their own data and determine what can be shared with whom.

The secondary material content chapter of the Circularity KIT explores how the secondary material framework contributes to heightened transparency, empowered data management, and streamlined communication, ultimately fostering a more sustainable and interconnected automotive ecosystem.

Business Context

Use Case / Domain Explanation

This user journey illustrates the data exchange process through Catena-X in the context of secondary material content. The user journey outlines the various stakeholders along the value chain and within the individual tiers and their involvement.

Figure 4

User Journey - SMC

The user journey follows the same process during all four lifecycle stages and differ in data quality as stated below. Further information to the lifecycle stages can be found in the Traceability KIT.

Lifecycle Stage	Explanation	Example
As Designed	Development phase: Initial estimation of secondary material content	The company that wishes to procure a component requires an initial estimate from the supplier regarding the elements of the SMC.
As Planned	Planning phase: Concretization of the secondary material content	The company chooses a supplier based on the proposals received and obtains more detailed information about the SMC as the supplier can plan the component with greater precision.
As Ordered	Ordering phase: Calculation of secondary material content on the basis of supplied components	The ordering phase occurs before the start of production, allowing for the calculation of the SMC information based on the specific parts and materials that are being supplied.
As Built	Production phase: Ongoing calculation after start of production	During the production process SMC information are regularly exchanged between supplier and OEM.

Semantic Models

There are different scenarios in which SMC Data can be exchanged. According to the semantic model framework, this implies that there is a specific data model for each purpose (scenario).

In order to ensure efficiency by avoiding redundancy and maintaining multiple data models, the concept of a shared aspect model was used: This means that there is one Secondary Material “base model”, which is the SecondaryMaterialContent. This serves as an enabler for data modelling and not for data exchange itself, it is bad practice to use it for data exchange.

Instead, SecondaryMaterialContentCalculated or SecondaryMaterialContentVerifiable should be used when exchanging SMC data, depending on the actual scenario.

The main difference between these data models, is whether the data is based on assumptions or a prognosis and is therefore not fixed, in which case SecondaryMaterialContentCalculated is to be used. On the other hand, once the data is actually measured and can therefore be verified, the SecondaryMaterialContentVerifiable should be used. It is important to note that the models now include the same properties and can only be differentiated by the name of the relevant data model.

In the table below, different scenarios are described to clarify which data model is used in which case.

Scenario	Description	Example from Practice	Data Model
Assumption-based SMC data exchange	The SMC data exchanged in this scenario is based on assumptions made by considering various factors	Tier-n requests an initial estimate of the SMC data for a new component from its supplier.	SecondaryMaterialContentCalculated
Prognosis-based SMC data exchange	In this scenario, SMC data is exchanged based on a prediction or forecast of future events in the automotive sector.	When the production of a previously produced car is continued, a prognosis of the SMC is made based on the previous production.	SecondaryMaterialContentCalculated
Measured-information-based SMC data exchange	In this scenario, the SMC data that is exchanged is based on actual measured information and data. The relevant data is therefore verifiable.	During the production of a component, the order information of the used material clearly indicates the SMC of the used materials.	SecondaryMaterialContentVerifiable

Figure 5

Depiction of SMC Data Models - SMC

The next part provides an overview of the secondary material content (SMC) calculation framework, including relevant data points, the calculation of SMC, and links to the data model and GitHub. The goal is to create a common basis for the data relevant for the SMC. Based on this, steering for secondary material content (SMC) and secondary material quota (SMQ) is possible.

A. Introduction to the Semantic Models

The semantic model is based on data points regarding material and order data.

There are different timestamps to which data for SMC is relevant.

To ensure the accuracy of the data and account for varying availability and quality of the information, it is important to identify at which step of the process data is exchanged. The process is divided into four steps, which are explained below.

Timestamp Linked to Traceability KIT	Explanation	Concept in Catena-X developed	Data Models that need to be filled
a. Supplier Inquiry/As Designed	This is the initial phase of the process where the supplier is inquired about the design of the product. The data exchanged in this phase is an initial estimation of secondary material content.	Concept currently not developed	N/A
b. Supplier Selection/ As Planend	In this phase, the supplier is selected, and the data exchanged is based on the planned production and concretized to the previous phase.	Concept developed	1. Part as Planned (Component) 2. SMC
c. SOP/ Industrialisation/ As Ordered	This phase involves the ordering and the start of the production process. The data exchanged is based on the actual production process.	Concept currently not developed	N/A
d. Post-SOP/ Serie/ As Built	This is the final phase of the process where the product is built, and the data exchanged is based on actual product specifications. The data exchange during this phase is regular and allows for the most precise calculation of SMC of all the stages.	Concept developed	1a. Serial Part (Component) or 1b. Batch and 2. SMC

In addition to filling out the data model for Secondary Material Content, other data models must also be completed to ensure adequate information and compatibility within Catena-X. During the As-Planned phase, the Part as Planned (Component) data model must be filled in addition to the SMC data model. Once the as-built phase is reached, the serial part (Component) data model must be filled to provide information as manufacturer partID, and customer partID. As such, these values are not included in the SMC data model.

1. Material

The Model is designed to address the material at the lowest level requiring descriptive information, such as the material name in accordance with a standardized format, as well as the name and code of the referenced standard (materialNameStandardizedValue; referencedStandard; referencedStandardID). For example, a material name may be given based on the ISO 1043 standard, in which case ISO would be the referenced standard and ‘1043’ the referenced standard ID. The material class (materialClass) must be provided in accordance with the VDA standard 231-106. To provide relevant data regarding the material mass per declared unit of the material, the unit of measure, such as gram or kilogram (unitOfMeasureKey), must first be defined. Next, the gross material input weight (grossMaterialInputMass) as well as the net mass of the material (materialNetMass) shall be provided.

Essential material characteristics that are mandatory within the data model include the use of bio-based materials and their material class (bioBasedClass), as well as the percentage of material weight of each primary and secondary bio-based material (primaryBioBased; secondaryBioBased). For secondary bio-based material it can be chosen whether a mass balancing approach was followed or not (isMassBalanced). Further information on mass-balancing can be found under B. Accounting for chain of custody models.

Further, information regarding inorganic/fossil-based materials is required. The percentage of primary inorganic/fossil-based material weight (percentageOfMaterialWeight) shall be provided. When it comes to secondary material, the percentage of material weight of chemically and mechanically recycled pre-consumer and post-consumer material according to ISO 14021 should be included (percentageOfMaterialWeight). Post-Consumer material is divided into two streams: Post consumer material from end-of-life vehicles as well as post consumer from other sources. When chemical or mechanical recycling has been applied, it is important to disclose information whether a mass balancing approach was followed (isMassBalanced).

Definition of pre-consumer material:

“Material diverted from the waste stream during a manufacturing process. Excluded is reutilization of materials such as rework, regrind or scrap generated in a process and capable of being reclaimed within the same process that generated it. Pre consumer material can be used in form of recovered or recycled material as a substitute for primary material.”

Definition of post-consumer material:

“Material generated by households or by commercial, industrial and institutional facilities in their role as end-users of the product which can no longer be used for its intended purpose. This includes returns of material from the distribution chain. Post-consumer material can be used in form of recovered or recycled material as a substitute for primary material.”

Optional Information, such as Reutilization

Optional information can be included to enhance the quality of the provided data, such as the percentage of material weight of reutilization material content (additionalInformation).

Definition of Reutilization:

“Reutilization of materials such as rework, regrind or scrap materials generated within the process and capable of being reused within the same process that generated it. Any operation by which products or components that are not waste are used again for the same purpose for which they were originally intended. Reutilization allows waste to be reduced and materials can be kept in the cycle.”

Even though Reutilization fosters the avoidance of waste, it does not count as recyclate according to ISO 14021 and is an optional attribute for this data model.

If available, the name of a certificate verifying the recycling content and a link to its PDF validating the provided information can be included (certificate).

Figure 6

Material Characteristics

The schematic depiction above provides a visual representation of the connection between various material characteristics, facilitating an understanding of how different data points relate to each other and contribute to the calculation of SMC.

2. Order Data

To clearly identify the order and relevant material, the order number (orderNumber) can be provided on an optional basis.

B. Accounting for Chain of Custody Models

Please see the Catena-X Product Carbon Footprint (PCF) Rulebook for further information. Chain of custody is an administrative process by which information about materials is transferred, monitored, and controlled as those materials move through supply chains [ISO 22095:2020]. There are in principle four chains of custody models possible, illustrated in the figure below. Their common objective is to guarantee correct bookkeeping and to corroborate a link between in-going content, e.g., ‘sustainable’, ‘recycled’ or ‘organic’ by harmonized definitions, and the finally out-going product. They differ regarding physical or administrative links. Furthermore, they differ on the set of rules for balancing, and the possibility to keep materials streams segregated or not.

Figure 7

figure custody models ¹

The following table is adapted from the Mass Balance EMF White Paper and provides high-level explanations and differentiations for the four chain of custody models:

Model	Explanation	Example
Identity Preservation	It is possible to physically track the product to its desired origin, ensuring unique traceability and physical separation of products from other sources along the supply chain.	Buying food from a single certified producer.
Segregation	Consists in the aggregation of volumes of products of identical origin or produced according to the same standards in one stock item.	Buying food from a trader that exclusively handles identically certified supplies.
Mass Balance	Considering the output, no physical or chemical difference exists between in-scope and out-of-scope. It involves balancing volume reconciliation to ensure the exact account of volumes of in- and out-of-scope source is maintained along the supply chain, provided that the volume or the ratio of sustainable material integrated is reflected in the product produced and sold to customers. This model requires that a reconciliation period is defined (e.g. a month, a year).	Buying a certain percentage of a supply from certified origin. Applies to, e.g., sustainable forestry for wooden materials, recycled, bio-based or renewable materials, organic cotton
Book and Claim – Restricted Certificate Trading	The certified product / component is disconnected from the certification data but belongs to the same production system or value chain. The certified product evolves in separate flows from the certified supply. Certificates are issued at the beginning of the supply chain by an independent body reflecting the sustainable content of supplies. The intended outcome is that outputs from one supply chain are associated with total claims corresponding to the certified input.	Buying material with renewable/recycled/ biobased content. Certificates with guarantee of origin or comparable certifications declaring e.g. recycled, renewable, biobased content. CO2 capture certificates from a production system controlled by the company, e.g. carbon capture and storage.

For calculating the PCF according to the Catena-X rulebook all types of models may be taken into account, if the requirements listed below are met and an independent third-party chain of custody verification for the balance of materials is available. The balance between input and output shall be correct.

The mass balance approach helps enabling fossil raw materials to be replaced by more sustainable alternative materials (e.g. with recycled content, bio-content). In contrast to a segregated use of alternative raw materials, mass balance enables to use existing production networks with minimized or no investments into new process technologies and production facilities. A book and claim model can be applied when there is no direct connection between the final product and the certified supply. An example for a book and claim model is applied in green electricity markets and receives more attention in other sectors as a way to support circular transformation of the industry, therefore it is accepted as a solution. There will be a regular review by Catena-X to decide about the further necessity.

Guiding Principles

In implementing chain-of-custody methods, including the mass balance one, the following set of guiding principles shall be fulfilled:

The use of chain-of-custody approaches shall achieve significant changes and an effective transition towards a more circular, more bio-based and lower GHG emissions production in complex value chains.
The choice and implementation of chain-of-custody approaches and models shall be transparent, clear, and credible – abiding by relevant standards such as ISO and CEN. Such credibility can also be achieved but is not limited to accepted third-party certification schemes, e.g. ISCC PLUS, REDCert2 and RSB.
Note: Certification Schemes are not yet available in all sectors.
Labels and claims referring to chain-of-custody controlled specified characteristics and used on products shall fulfill the following requirements:
- description of the chain-of-custody approaches and models
- accurate and appropriate implementation of the chain-of-custody model
- compliant with existing standards and regulations
- non-misleading
In case the “specified characteristic” content in products cannot be measured and verified, labels and claims products may reflect this in ways that clearly differentiate and specify the actual content.
No double counting: A reliable bookkeeping system shall be installed at each operating site to avoid the sales of a greater amount of alternative attributed products than physically available in the company.
Additional requirements for mass balance chain of custody approach:
The operating sites in the spatial boundaries for mass balancing are under the operational control of the same company/corporate group/joint venture.
It shall be technically possible according to standard industry practice to produce a mass balanced product from an alternative feedstock. The share of mass-balanced material can be technically lower than the attributed share.
Applied emissions factors for the mass balance system boundaries shall be material and process specific.

For the SMC data model, information whether a mass-balanced approach has been applied or not can be provided in the data model.

C. Calculation Logic for SMC

The secondary material quota (SMQ) is a KPI measuring the usage of secondary materials within a vehicle. A vehicle can be defined as the sum of its individual components. Therefore, the secondary material content (SMC) is defined as the ratio between secondary material used and total material used on component level. To enable steering for secondary material content on the component level, it is important to establish a common understanding of the SMC of a single material. Based on the data model and information provided earlier, the SMC of a material can be calculated. The SMC can be divided into different pillars: Pre-consumer material and Post-consumer material and, optional: Reutilization material content

All secondary material usage types are being expressed as percentages of the relationship between secondary materials and total materials used.

1. Pre-consumer material content

pre consumer material content equation

Definition of pre-consumer material:

2. Post-consumer material content

post consumer material content equation

Definition of post-consumer material:

3. Optional: Reutilization content

Definition of reutilization:

“Reutilization of materials such as rework, regrind, or scrap materials generated within the process and capable of being reused within the same process that generated it. Any operation by which products or components that are not waste are used again for the same purpose for which they were originally intended. Reutilization allows waste to be reduced and materials can be kept in cycle.”

SMC and SMQ Calculation

The SMC calculates as the sum of the above defined secondary material usage types:

SMC Equation

In the above-described manner, the secondary material content is to be calculated for every component of the vehicle.

The SMQ as a KPI defined on vehicle level which is calculated based on the individual SMC’s of the respective components:

SMQ Equation

It is important to note that data quality may vary during different stages of the process, and this should be taken into consideration to ensure the highest level of data accuracy.

To calculate the average portion of, for instance, the amount of mechanical recycling of post-consumer material content in the whole material, the values along the data model must be multiplied. For example, the content of inorganic or fossil-based material, content of secondary inorganic or fossil-based material, post-consumer material content, and mechanical recycling would be multiplied as can be seen in the schematic depiction below.

Figure 8

material_characteristics

D. Data Models and Github

The relevant data models can be found via the following links on GitHub:

The open availability on GitHub allows companies to combine their own internal target guidance programs with the data models from Catena-X to SMC.

End of Life / Dismantling Services

Introduction

Closing Loops, Preserving Resources: Creating tomorrow's EoL landscape and empower the circularity

As part of the Circularity KIT, we are committed to developing services for the future of the circular economy in the end-of-life (EoL) sector of vehicles. This phase represents an important stage where decisions are made regarding the fate of vehicles and their components after their initial use. Recognizing the immense value of the world's limited resources, we are dedicated to minimizing waste and maximizing resource efficiency.

One of our key strategies involves creating a framework for an improved communication among all stakeholders involved in the EoL phase. This collaborative approach allows us to consider the needs and requirements of all participants, facilitating the collection and exchange of essential information. Importantly, we view the end of a vehicle's life as the beginning of a new one in the context of resource conservation.

Our overarching vision is to create a landscape that closes loops and preserves resources, ultimately empowering circularity in the industry. We aspire to provide digitized and scalable EoL services that align with circular economy principles and prioritize the preservation of components and materials. Simultaneously, we are committed to follow present and future changes in laws and regulations, which emphasizes environmentally friendly vehicle disposal and the recovery of critical raw materials (CRMs), aligning with the growing demand for closing component and material loops.

Our mission centres on empowering EoL and maintenance stakeholders by fostering continuous collaboration within the Catena-X Network and beyond. Through the Circularity KIT working group, we aim to develop and align various means, including data, business, and network models, to empower all stakeholders involved in the EoL phase. This mission is closely tied to our vision of promoting digitized and scalable end-of-life services across the industry while upholding the principles of circular economy.

Our strategy for achieving these goals involves several key steps. Firstly, we aim to enable EoL service models through data sharing based on digital twins (DT). This approach allows for efficient information sharing in an interoperable, standardized manner, which, in turn, supports dismantling and recycling operations. Furthermore, we are actively engaging with all relevant stakeholders, including policymakers, product designers (for circularity), and EoL service providers, to promote new "R-approaches" and facilitate their implementation.

Ultimately, our efforts provide essential support for the digitalization and automation of the EoL phase, with the ultimate goal of closing loops in the automotive sector. Through these digitized and scalable EoL services, we aim to contribute significantly to sustainable development and resource conservation, aligning with the principles of the circular economy.

Business Context

Data Journey "End-of-Life"

The "Data Journey" represents the entire process of dismantling an End-of-Life (EoL) vehicle. Each process step is accompanied by CX data models that would be necessary for digitally representing the individual process steps. This enables us to elevate the data journey for the dismantling process to a digital level and to gain an understanding of which data attributes and aspect models are required for each process step. It forms the foundation for the creation of digital EoL-solutions and the use of robotics.

Figure 9

Data Journey - End of LIfe

Future additions include data models for the following topics:

Decommissioning Certificate
Material for Recycling
Adress Aspects
ID Conversion
Certificate of Dismantler
Diagnostic Data
Physical dimensions
Mandatory dismantling
Demand request
Compatibility of components/ Design changes history
Quality issue history
Technical drawings & specifications
PCF Information

User Journey "Certificate of Decomissioning"

The user journey "Certificate of Decommissioning" (CoDM) describes the moment at which a vehicle is transferred into the End-of-Life (EoL) phase from the perspective of an authorized collection point for EoL-vehicles, such as an authorized dismantling facility. The CoDM resembles the official Certificate of Destruction (CoD) but marks the starting point of the upcoming CX concept of a digital CoD.

Figure 10

User Journey CODM

Data Model and GitHub

The relevant data model can be found on the following link on GitHub: https://github.com/eclipse-tractusx/sldt-semantic-models/tree/main/io.catenax.decomissioning_certificate/1.0.0

The open availability on GitHub allows companies to combine their own internal target guidance programs with the data models from Catena-X to the EoL-Services.

CE-Assistant

Introduction

Empowering Circular Economy Decisions: Introducing the Circular Strategy Assistant

In the dynamic landscape of sustainability and resource conservation, the Circular Strategy Assistant (CE-Assistant) emerges as a pioneering solution, providing decision support for the selection of optimal strategies concerning end-of-life vehicles. At its core, the CE-Assistant tackles the task of evaluating and choosing from a spectrum of R-Strategies—namely Reuse, Remanufacturing, Recycling, and Recovery.

Rooted within the principles of Catena-X, the CE-Assistant is deeply aligned with a comprehensive assessment process that guides its functionality. This process is chiefly anchored in the Catena-X Digital Twin Framework, which encapsulates the essence of virtual representation and real-world insights.

Central to this endeavor is the CE-Assistant—a set of standards, aspect models, APIs, system architectures, and decision logics—all designed to foster the development of data-centric, Catena-X compliant decision support systems for Circular Economy Strategies. The core circularity lies in the orchestrated flow of engineering information—a collaborative effort involving entities across the automotive value chain.

The concept of Digital Twin (DT) serves as the backbone, offering a holistic virtual counterpart of assets. Defined with precision, the DT embodies a set of unique identifiers, an evolving spectrum of aspects, connectivity to diverse data sources, and the capacity to traverse the entire lifecycle of assets, encapsulating both individual and fleet-level knowledge.

In accordance with IDSA and Gaia-X principles, interconnectivity and data sovereignty, the CE-Assistant thrives on the principles of interoperability, substantiated by the Connector KIT (EDC) and Data Chain KIT (Item Relationship Service - IRS).

Undeniably, the selection of Circular Economy Strategies necessitates a comprehensive evaluation of emissions, natural resource preservation, energy management, and waste reduction. However, the effectiveness of such evaluation’s hinges on access to granular data encompassing the vehicle’s history, components, materials, and condition.

This is precisely where the CE-Assistant can help by supporting a user-centered approach that bridges the gap between data availability and informed decision-making. By offering transparency into the environmental implications of diverse circular economy strategies, the CE-Assistant facilitates swifter, well-informed, and efficient decisions rooted in the digital twin's insights.

Business Context

Business Context The CE-Assistant provides decision support and circular strategies, enabling several key features for businesses:

Component-Level Decision Support: The KIT provides decision support for selecting circular strategies at the component level.
Efficient Data-Driven Decisions: Users can make faster and more efficient decisions based on data analysis.
Enhanced Circularity: The KIT contributes to increasing the circularity of products and meeting reuse quotas.
Sustainability Milestones: It helps achieve sustainability indicators and goals.
Transparency on Secondary Materials: The KIT offers transparency regarding the availability of secondary materials.
Streamlined Vehicle Dismantling: It optimizes the process of vehicle dismantling for improved resource recovery.

Use Case / Domain Explanation

The User Journey describes the system interaction of the CE Assistant with the user, the Dismantling Lead, with the aim of providing a recommendation for a component-level circular strategy for end-of-life vehicles. This involves breaking down the process of holistic decision-making into individual process steps and identifying the interaction with the user/system at each process step.

Figure 11

Figure UserJourney CE Assistant

Whitepaper

If you are eager to dive deeper into the world of the CE-Strategy Assistant, including its data provision via the Digital Twin and expert insights on technically feasible circular strategies and environmentally friendly choices, we invite you to explore our informative publications.

End-of-life decision support to enable circular economy in the automotive industry based on digital twin data

Abstract: With the EU Green Deal and the UN Sustainable Developments Goals, the vision of a greenhouse gas-neutral and resource-efficient economy is already firmly anchored in world politics. In this context, the automotive industry faces many challenges including the increasing scarcity of natural resources, a rising demand in terms of sustainable vehicle design, production and materials sourcing. Due to all this, end-of-life decisions regarding dismantling have become increasingly important. A high proportion of secondary materials will be required in the vehicles of the future. To response to these challenges, companies have turned their focus towards the circular economy as a central approach to close material loops. In the German research project “Catena-X” a new data ecosystem with digital twins is one enabler that is being developed. The digital twins represent a promising approach to the circular economy by ensuring transparent, product-specific and end-to-end data exchange throughout the entire product lifecycle, from the material sourcing to the eventual dismantling and recycling. As one particular and unique solution, a decision framework that facilitates the best circular strategy at the end of a vehicle's life is developed and presented in this paper. The underlying data-driven decision support framework is based on circular economy KPIs. This includes material, components and specific vehicle KPIs to best identify the most suitable circular strategy. The framework was methodologically developed by an interdisciplinary team of partners, who are stakeholders throughout the value chain and participants in the Catena-X project. An integrated approach of user-centered design, an adapted version of the V-model and the Scaled Agile Framework were used for the methodology in the development of the solution. The paper presents the concept of a digital twin for a decision support system, that includes a central decision logic that also includes the relevant KPIs and a survey for evaluating the decision logic utilized with a chosen dismantling company.
Link: End-of-life decision support to enable circular economy in the automotive industry based on digital twin data - ScienceDirect

Empowering End-of-Life Vehicle Decision Making with Cross-Company Data Exchange and Data Sovereignty via Catena-X

Abstract: The mobility sector is the world’s second-largest producer of energy-related CO2 emissions, and it is facing a global resource shortage. The demand for circular products, the use of secondary materials in future vehicles, and the need for sustainable business models in the mobility sector is increasing. However, a transparent and end-to-end data exchange throughout the entire value network is missing, which is hindering an efficient circular economy. Relevant information on the vehicle, its components and materials at the end of the product life cycle are often missing. In this context, this paper presents a decision support system based on Digital Twin data for a circular economy solution as a software application. It was developed within the German research project Catena-X following an integrated approach of user-centered design, the V-model, and within the Scaled Agile Framework. By combining these methodological approaches, customer-oriented solutions were developed and continuously improved at each stage of development to shorten the time-to-market. Catena-X is based on Gaia-X principles. In Gaia-X, necessary core services are developed, and contraction negotiation for data exchange and usage policies is enabled and implemented. The decision support system provides important information about the exact composition and condition of the vehicle, its components, and its materials. Thus, it helps to improve efficiency, sustainability, and the implementation of the circular economy. The decision support system was tested and validated with a use case that provided Digital Twin data on the end-of-life vehicle.
Link: Sustainability | Free Full-Text | Empowering End-of-Life Vehicle Decision Making with Cross-Company Data Exchange and Data Sovereignty via Catena-X (mdpi.com)

Digital Twins for Circular Economy - Enabling Decision Support for R-Strategies

Abstract: Digital twins (DT) for circular economy (CE) offer a promising approach as part of digital data ecosystems for more sustainable value creation. By mapping and analyzing product, component and material specific data along the lifecycle, it is possible to address current challenges such as climate change and resource scarcity. Within Catena-X, specific solutions based on this cross-company exchanged data and information are developed. Here, the “CE-Assistant” is presented. It is an application, which identifies the best CE-Strategy based on DT data at the end of a vehicle's life.
Link: OA_Mügge_6-2022 | INDUSTRIE-MANAGEMENT

Logic / Schema

In order to evaluate which R-Strategy can be applied to individual components, instance-specific data must be available. This is ensured using DT data throughout the product lifecycle. Such an DT enables the collection of instance-specific data on the product, and thus provides the missing EoL data for vehicle disassembly.

Depending on the decision-making step, instance specific data for the vehicle disassembly is partly necessary or product specific data is sufficient. Decision support regarding the best R-Strategy is preceded by the logic for the technical feasibility. Thus, only when the R-Strategy is technically feasible, it must be checked for other indicators.

The outcome of the technical feasibility is to analyze if an R-Strategy has to be excluded at the beginning based on regulatory requirements regarding an R-Strategy or a defect in functionality of specific components.

The process is started by entering the vehicle identification number (VIN) into the system, thereby requesting the corresponding Catena-X data. The registered companies in the Catena-X network act as data providers for this vehicle-specific data, as they register respective assets and sub-models. Catena-X Shared Services handle existing data models, contract, usage and access control policies, and ultimately the final data exchange.

The system shows the first information, such as corresponding vehicle, component and material based on data from the DT. This data is provided for the first overall manual inspection and evaluation. After that, the user selects the most relevant components for the R-Strategy decision. The decision logic is applied for this component and the possible R-Strategies are identified.

The core process means in a chronological order: The basic reuse-potential, material composition and remaining lifetime in comparison with the specific thresholds and the disassembly capability.

If one or more of these criteria are not fulfilled, the component will only be assigned to recovery or recycling. If the component qualifies for disassembly, a manual visual inspection and a functional check are conducted. For components, where the visual condition is relevant, such as body parts and interior components, the visual inspection is conducted first. In contrast, components, for which the technical condition is of significant relevance, such as engines and gearboxes, are first subjected to a functional test. Here, the data can also be provided in the Catena-X network as an update of the DT. Thereafter, a quality comparison of the component condition with threshold values takes place. When the quality is insufficient for reuse, the technical check for remanufacturing is carried out chronologically: Assimilability, cleanability and restorability/upgradability. Finally, a possible strategy is given to the user as a result.

Figure 12

user story flowchart

Secondary Marketplace

Introduction

A secondary marketplace is fundamental to establish a circular economy where components and materials are available and offered to the interested users creating new value chains and extending the life of the parts and the materials before becoming waste. Digital platforms offering marketplace services are essential to enable trading of secondary materials and components, provide transparency into supply and demand that potential buyers and sellers can expect.

The main goals of the Marketplace are: (1) to match the demand and the supply of available components and secondary raw materials and (2) to provide transparency on sales opportunities for used components which can be, for example, reused or re-manufactured.

If offered, additional services such as grading, certifications for the offered listings (components or secondary materials) and transport handling and logistics could support trading processes.

Business Context

A secondary marketplace enables closing the loop on economical and physical layers. Following the logic described in the previous chapter, there could be multiple scenarios related to R-strategies on how secondary marketplaces enable a circular economy.

Potential sales scenarios:

Dismantling companies selling old components and material/scrap;
Automotive manufacturers selling old unused components;
Automotive manufacturers selling production waste and scrap;
and others.

Potential purchase scenarios:

Automotive companies buying components for re-manufacturing;
Workshops buying components for re-use;
Recyclers buying production waste and scrap;
and others.

In all of those cases, having additional information (e.g. product carbon footprint or digital product passport details) on the products offered on the marketplace is beneficial.

User Journey and Architecture Overview

In general, there are several goals that buyers and sellers pursue on a secondary marketplace:

As a (Core) Purchaser, I want to search and filter for market supply on OE number level to match the market offers towards my demand.
As a (Core) Purchaser, I want to reach as many possible sellers as possible to purchase parts that I cannot procure today. This includes brokers I don't buy from today.
As a (Core) Seller, I want to place offers on the marketplace with standard upload tools and manually.
As a (Core) Seller, I want to reach as many possible customers as possible to maximize my turnover. This includes customers I don't sell to today.

The key user journey relevant in Catena-X circular economy area relates to the need of a buyer to have full reliable information on a product that he is intending to purchase. This is especially important given that many buyers are looking for parts for re-manufacturing or re-use, where product quality plays a vital role. Furthermore, in case of recycling, recyclers are interested to know material composition and additional information that would influence their purchasing decision.

Some information could be provided by a variety of data models, but the highest value lies within the generic digital product passport (and by extension, battery passport, sealant passport, transmission passport). When a seller is publishing a listing with a product that he is willing to sell, there is only a limited amount of information he can provide with it, mostly the one available from the visual inspection or on-board data (such as mileage, OE-number, brand) as well as logistical/ sales information (such as location or price). When a potential buyer views the listing, he should have a possibility to request additional details from a data provider of the generic digital product passport (if available) for that product (see diagram below). More information on the digital product passport can be found in the Ecopass KIT.

Figure 13

User Journey - Secondary Marketplace

This process is reflected in the architecture for communicating with the Catena-X network and data providers of the battery passport data model, as presented below.

Figure 14

Communication Architecture

When it comes to the data exchange schema and other details, see the Triangle for Secondary Marketplace document for more information on how such a request could be realized within Catena-X environment and according to applicable guidelines (e.g. on interoperability and data sovereignty). In a decentral environment, such attributes as manufacturer part ID and OE number play a vital role in order to get access to the right component and the right data model at data provider’s side.

Semantic Models

In the following, relevant semantic models for the secondary marketplace are listed. For further information about the listed data models please refer to the Catena-X standards library for the respective data model, marked as “CX-“, which contains the standardized data models with further descriptions and explanations. The standards library can be founded here: Catena-X Standard-Library

The Marketplace Offer is an aspect model that is complementary to the concept of a secondary marketplace. It described a product (e.g. a used, dismantled component) that is placed for sale onto the marketplace, with key supporting information such as quantity, quality, or price. It provides essential information for potential buyers and could be used in the future to exchange product information between multiple marketplaces. This model can therefore be used to exchange offers between multiple marketplaces. As there is no exchange scenario defined yet, the Marketplace Offer is a recommendation and non-normative, since it is so far concerning the business application-internal data structure only. More information on this aspect model can be found under CX-0035 in the standards library or under the following link: Marketplace Offer

Additionally, two other aspect models could play a supporting role for secondary marketplaces.

The Return Request aspect model could be used to flag a vehicle or product to indicate that there is a demand or a request for return. It specifies the aspect of the recall of a vehicle part and thus provides the information whether and why a return request exists for a product. More information on this aspect model can be found under CX-0033 in the standards library or under the following link: Return Request

The Product Passport aspect model could provide reliable details on the product characteristics or lifecycle information, therefore complementing the basic Marketplace Offer information. More information on this aspect model can be found under CX-0103 in the standards library or under the following link: Digital Product Passport

Glossary

Term	Definition	Source
Aggregate State/ State of Matter	State of matter (German: "Aggregatzustand") is one of the distinct forms in which matter can exist. Three states of matter are observable at ambient conditions and free of electrical charge: solid, liquid, gas	State of matter - Wikipedia
Base Quantity	The International System of Quantities defines seven base quantities. The set of base quantities is chosen by convention where no base quantity can be expressed in terms of the others, but where every quantity in the system can be expressed in terms of the base quantities.	International System of Quantities - Wikipedia
Bio-based Materials	Material of biological origin excluding material embedded in geological formations and/or fossilised	European Commission, Categorisation System for the Circular Economy, doi:10.2777/172132, P. 9
Biomass	Material of biological origin, excluding material embedded in geological formations or transformed material of biological origin, excluding material embedded in geological formations or transformed to fossilized material and excluding peat	DIN ISO 14021
By-Product	Substance or object, resulting from a production process, the primary aim of which is not the production of that item, and does not constitute waste (as defined in Directive 2008/98/E on waste)	European Commission, Categorisation System for the Circular Economy, doi:10.2777/172132, P. 9
CAS Number	a unique numerical identifier assigned by the Chemical Abstracts Service (CAS) to every chemical substance described in the open scientific literature. / Except for a small selection of most common substances released under CC-BY-NC license the CAS numbers are a proprietary identification scheme to be licensed from CAS (USA)	CAS Registry Number - Wikipedia
Chain-of-Custody approach	Mass balance is one of several well-known chain of custody approaches that can be used to track the flow of materials through the value chain. The total quantity of the content in question is tracked through the production system and the allocation of this content is made to the end products based on verifiable accounting. The goal of this method is to ensure proper accounting and to confirm a link between the incoming content (e.g., "sustainable," "recycled," or "organic" according to some definition) and the eventual outgoing product.	https://www.basf.com/global/documents/de/sustainability/we-source-responsibly/Mass-Balance-White-Paper-2020.pdf
Chemical Composition	Chemical composition refers to identity and number of the chemical elements that make up any particular chemical compound. In order to provide unambiguous information, "chemical element" and "chemical compound" must be defined as context.	Chemical composition - Wikipedia
Chemical Recycling	Chemical or feedstock recycling refers to the conversion of plastic polymers into their monomers or chemical building blocks or basic chemicals, i. e. depolymerisation by means of thermochemical or chemical processes, although there is currently no uniform, legally binding definition [13].	Background Paper on Chemical Recycling - German Environmental Agency, Dec 2020
Circular Economy	The circular economy is a model of production and consumption, which involves sharing, leasing, reusing, repairing, refurbishing and recycling existing materials and products as long as possible. In this way, the life cycle of products is extended.	European Parliament
Closed-Loop-Recycling	In a closed loop, the secondary material from one product system is either reused in the same product system or used in another product system without changing the inherent properties of the material.	PCF Rulebook
Component	Part or small assembly of parts used as part of a larger assembly	Article 2 Definitions 200053EG
Compostable	Characteristic of a product, packaging or associated component that allows it to biodegrade, generating a relatively homogeneous and stable humus-like substance.	DIN ISO 14021
Consumer	Any natural person who, in contracts covered by this Directive, is acting for purposes which are outside his trade, business, craft or profession	2011/83/EU on consumer rights
Co-Product	Any two or more products coming from the same unit process or product system.	PCF Rulebook, DIN EN ISO 14067, Feb. 2019, p.22
Degradable	A characteristic of a product or packaging that, with respect to specific conditions, allows it to break down to a specific extent within a given time.	DIN ISO 14021
Disposal	Disposal means any of the applicable operations provided for in Annex IIA to Directive 75/442/EEC, for instance deposit into or onto land, land treatment, deep injection, surface impoundment, release into water body, biological treatment, physico-chemical treatment.	Guideline 2000/53/EG
Dismantling ability	The ability of components to be removed from the vehicle.	ISO 22628:2002-02
Dismantling Information	All information necessary for the proper and environmentally sound treatment of an end-of-life vehicle. It is provided to authorized treatment facilities by vehicle manufacturers and suppliers in the form of manuals or electronic media (such as CD-ROMs, online services).	Guideline 2000/53/E
Downcycling	Downcycling, or cascading, is the recycling of waste where the recycled material is of lower quality and functionality than the original material.	Downcycling - Wikipedia
Ecological Assessment	Compilation and evaluation of the inputs, outputs, and potential environmental impacts of a product system throughout its life cycle	Article 2 Definitions 200053EG
Economic operators	Manufacturers, distributors, take-back points, motor vehicle insurance companies, dismantling facilities, shredder plant operators, recovery facilities, recycling facilities, as well as other facilities for the treatment of end-of-life vehicles, including their components and materials.	Guideline 2000/53/EG
End-of-Life	The point at which a product or component is taken out of use	Article 2 Definitions 200053EG
End-of-Life Vehicle	Vehicles that are considered waste under Article 1 letter a) of Directive 75/442/EC	Article 2 Definitions 200053EG
End-of-Waste	The end-of-waste state for waste in Europe reached when the material is no longer considered a waste under the national implementation of the Waste Framework Directive.	PCF Rulebook, EN 15804
Energy recovery	Energy recovery includes any process that refers to the use of waste as a raw material or the treatment of waste that cannot be recycled. The aim is to recover energy from materials and associated with this, to convert them into usable heat, electricity or fuel.	U.S. Environmental Protection Agency (2016) Energy Recovery from Waste
Fossil Materials	Fossil raw materials are all raw materials derived from organic material. They include coal, crude oil and natural gas.	Federal Geothermal Office
Hazardous substances	Any substance that is classified as hazardous according to Directive 67/548/EEC.	Guideline 2000/53/EG
ILCD Format	International Life Cycle Data Format	PCF Rulebook
Input	Product, material or energy flow that enters a unit process.	Pathfinder / PCF Rulebook
Intermediate Product	Output from a unit process that is input to other unit processes that require further transformation within the system	Article 2 Definitions 200053EG
Life Cycle	Consecutive and interlinked stages related to a product, from raw material acquisition or generation from natural resources to end-of-life treatment.	DIN EN ISO 14067, PCF Rulebook
Mass	In physics, mass is not the same as weight. Mass is both a property of a physical body and a measure of its resistance to acceleration. For disambiguation see definition of "Weight" below	Wikipedia
Mass-Balancing	Considering the output, no physical or chemical difference exists between in-scope and out-of-scope. It involves balancing volume reconciliation to ensure the exact account of volumes of in- and out-of-scope source is maintained along the supply chain, provided that the volume or the ratio of sustainable material integrated is reflected in the product produced and sold to customers. This model requires that a reconciliation period is defined (e.g. a month, a year).	PCF Rulebook
Material	Physical good used as input for production processes of goods or services or physical good supplied to a customer as output	Pathfinder / PCF Rulebook
Material Declaration	Material declaration (MD) is the process mandated to meet the obligations placed on (automobile) manufacturers, and thus on their suppliers, by national and international standards, laws and regulations.	IMDS Information Pages - Home - IMDS Public Pages (mdsystem.com)
Material Details	Collection of material information defined by given context in an information model	Catena-X definition
Material Identifier	Material Identifier is a alphanumerical identifier that serves programmatic functions (e.g., as data ID) but also satisfies chemical regulation (see material declaration) under national and international law.	Catena-X definition
Material Name	Trivial name (often name of a chemical group) used to denote some material in everyday speech or jargon. Entirely dependent on specific context.	Catena-X definition
Material Recovery	Material recovery is recovery by processes in which virgin material of the same substance is replaced or the material remains available for further material use.	Packaging Act § 3 para. 19
Material Type	Groups of materials defined by convention (e.g., IMDS) or ISO Standard (e.g., ISO 62474) in order to simplify communication of relevance of material information (in search or filtering)	IEC 62474 – Material Declaration
Mechanical Recycling	End-of-life materials can be processed via collecting, sorting, shredding, melting and transforming it into secondary raw materials for a new application. This form of recycling involves processes in which e.g. the polymer structure is not significantly changed, and plastic is preserved as a material. Thus, in terms of its complexity, mechanical recycling takes place at a lower technical level than chemical recycling.	Mechanical recycling (basf.com)
Glossary and methods Open-loop recycling	In open-loop recycling, the material is reused in other product systems and is inherent properties are changed (e.g. recycled material may have a different chemical composition, a different chemical structure or a higher concentration of dissolved impurities compared to primary material)	PCF Rulebook
Output	Product, material or energy that leaves a unit process.	Pathfinder / PCF Rulebook
Post-consumer material	Material generated by households or by commercial, industrial and institutional facilities in their role as end-users of the product which can no longer be used for its intended purpose. This includes returns of material from the distribution chain. Post-consumer material can be used in the form of recovered or recycled material as a substitute for primary material.	DIN ISO 14021
Pre-consumer Material	Material diverted from the waste stream during a manufacturing process. Excluded is reutilization of materials such as rework, regrind or scrap generated in a process and capable of being reclaimed within the same process that generated it. Pre-consumer material can be used in the form of recovered or recycled material as a substitute for primary material.	DIN ISO 14021
Primary Material	Raw material coming from the environment, as well as materials of differing stages of processing (Raw materials, semi- and finished goods), which are used in the production process for the first time.
Prevention	Measures to reduce the quantity and environmental harm of end-of-life vehicles, their materials, and substances	Guideline 2000/53/EG
Process	Set of interrelated or interacting activities that transform inputs into outputs.	DIN EN ISO 14067, PCF Rulebook
Producer	The vehicle manufacturer or the commercial importer of a vehicle into an EU Member State	Article 2 Definitions 200053EG
Product	Any good (tangible product) or service (intangible product)	PCF Rulebook
Production	Process of combining various inputs, both material (such as metal, wood, glass, or plastics) and immaterial (such as plans, or knowledge) in order to create output.	Production (economics) - Wikipedia
Production Waste	Waste generated in different industries in connection with production and the opposite to consumption waste, which primarily comprise municipal waste and waste comparable to it.	Production waste Concepts Statistics Finland
Raw Material	Primary or secondary material, that is used for production of a product.	Pathfinder / PCF Rulebook
Recoverability	The ability of components and/or materials to be directed to a recovery process from the waste stream.	ISO 22628:2002-02
Recoverability quote	The percentage of the mass of the new vehicle that can potentially be recovered and/or reused.	ISO 22628:2002-02
Recovered Material	Material that would have otherwise been disposed of as waste or used for energy recovery, but has instead been collected and recovered [reclaimed] as a material input, in lieu of new primary material, for a recycling or a manufacturing process.	DIN ISO 14021
Recyclate	Secondary raw materials that have been generated by means of the recovery of waste or are generated in the disposal of waste and are suitable for the production of products.	KrWG, Framework Waste Directive
Recyclability quote	The percentage of the mass of the new vehicle that can potentially be recycled and/or reused.	ISO 22628:2002-02
Recycled Content	Proportion, by mass, of recycled material in a product or packaging. The recycled content is the sum of pre-consumer material and post-consumer material.	DIN ISO 14021
Recycled Material	Material, that has been reprocessed from (reclaimed) material by means of a manufacturing process and made into a final product or into a component for incorporation into a product.	DIN ISO 14021
Recycling	Recycling is the process of collecting, sorting, and processing waste to release materials that can be reused for their original purpose or other purposes, except for the energy recovery. Energy recovery is the use of combustible waste for energy production by direct combustion with or without other types of waste, but with the recovery of heat.	DIRECTIVE 2002/96/EC
Reduce	Increase efficiency in product manufacture or use by consuming fewer natural resources and materials	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Refurbish	Restore an old product and bring it up to date (to specified quality level)	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Refurbishment	Includes the same process steps as remanufacturing, that is repairing, restoring, rebuilding and/or replacing. A refurbished product is not comparable to a new one but has been updated to a specific quality level and should be fully functional.	Refurbishing – Wikipedia
Refuse	Make product redundant by abandoning its function or by offering the same function by a radically different (e.g. digital) product or service	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Remanufacture	Use parts of a discarded product in a new product with the same function (and as-new-condition)	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Remanufacturing	Remanufacturing is a standardized industrial process that restores used products to their original performance level or better, with a warranty equivalent to or surpassing that of newly manufactured products. The remanufacturing effort includes dismantling the product, restoring and replacing components, and testing individual parts and the whole product to ensure it meets its original design and performance specifications, as seen from the customer’s perspective.	BS 8887-2:2009
Repair	Repair is the process of returning a faulty or broken product or component to a usable state. The effort put into the repair is minimal and only addresses the specified fault to ensure the useability of the product; however, the performance of the repaired part may not be guaranteed. The warranty for a repaired product is generally less than that of a new or remanufactured product and may only apply to the replaced or repaired component	BS 8887-2:2009
Repurpose	Use a redundant product or its parts in a new product with different function	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Resource (Rohstoff)	Resource that is used or can be used in a process. A resource can be of a material or immaterial nature. When the term "resource" is used in the context of environmental science, it refers to a "natural resource". Unlike here, the term resource is often used very narrowly in the sense of raw materials.
Resource Protection	Economical use of natural resources with the aim of preserving their quantity and function.
Rethink	Make product use more intensive (e.g. through product-as-a service, reuse and sharing models or by putting multi-functional products on the market)	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
R-Strategies	R-Strategies, as part of circular economy, encompass a range of sustainable resource management approaches that prioritize actions such as reuse, remanufacturing, recycling, and recovery. These strategies aim to extend the life of products and materials, reduce waste generation, and minimize environmental impacts by promoting the efficient and responsible use of resources throughout their life cycle, thus contributing to the implementation of the circular economy model.	Inspired by Potting et al.: Potting, J.; Hekkert, M.P.; Worrell, E.; Hanemaaijer, A. Circular Economy: Measuring Innovation in the Product Chain; Planbureau voor de Leefomgeving: Hague, The Netherlands, 2017.
Re-use	Re-use of a product which is still in good condition and fulfils its original function (and is not waste) for the same purpose for which it was conceived	European Commission, Categorization System for the Circular Economy, doi:10.2777/172131, p. 7
Reusability	The ability of components to be diverted from the waste stream and reused.	ISO 22628:2002-02
Reutilization	Reutilization of materials such as rework, regrind, or scrap materials generated within the process and capable of being reused within the same process that generated it.	Adapted from ISO 14021
Scrap	Iron and steel material in metallic form that is recovered in multiple life cycle stages, including steel production processes, the manufacturing processes of final products and the end of life of final products	Adapted from ISO 20915:2018
Secondary Raw Material	Secondary materials are any materials that are not the primary products from manufacturing and other industrial sectors. These materials can include scrap and residuals from production processes and products that have been recovered at the end of their useful life.	US EPA, 17.08.2023
Shredder	Any facility that is used to crush or shred end-of-life vehicles, including for the purpose of recovering directly reusable metal scrap.	Guideline 2000/53/EG
Treatment	Activities carried out after the end-of-life vehicle is handed over to a facility for the elimination of pollutants, dismantling, coarse crushing, shredding, recycling or preparation for disposal of shredder waste, as well as other activities related to the recycling and/or disposal of end-of-life vehicles and end-of-life vehicle components.	Guideline 2000/53/EG
Vehicle	Vehicles of classes M1 or N1 according to Annex II Section A of Directive 70/156/EC and three-wheeled vehicles according to Directive 92/61/EC, however excluding three-wheeled motorcycles.	Article 2 Definitions 200053EG
Vehicle mass	Unladen mass of the operational vehicle (code: ISO-M06), according to DIN ISO 1176, term 4.6: unladen mass of the dry vehicle (term 4.5) plus the mass of lubricants, coolant (if required), washing fluids, fuel (tank filled to at least 90% of the manufacturer's specified capacity), spare wheel(s), fire extinguisher, standard spare parts, wheel chocks, standard tool ship.	ISO 22628:2002-02
Waste	Materials, co-products, products, or emissions without economic value that the holder intends or is required to dispose of.	DIN EN ISO 14067, PCF Rulebook, Pathfinder
Waste Prevention	Waste prevention is any measure taken to ensure that a substance, material or article does not become a waste. It is used to reduce the amount of waste, the harmful effects of the waste on people and the environment, or the content of harmful substances in materials and articles.	Closed Substance Cycle Waste Management Act
Weight	In science and engineering, the weight of an object is the force acting on the object due to gravity. For disambiguation see definition of "Mass" above	Mass - Wikipedia

NOTICE

This work is licensed under the CC-BY-4.0.

Copyright (c) 2023,2024 Fraunhofer-Gesellschaft zur Foerderung der angewandten Forschung e.V. (represented by Fraunhofer IPK)

Original image taken from Mass Balance EMF White Paper, visually adapted for this purpose.↩

Circularity KIT​

Vision & Mission​

Introduction​

Vision​

Mission​

Business Context​

Circularity KIT Wheel​

Figure 1​

Use Case / Domain Explanation​

Material Accounting​

Introduction​

Material Accounting: Enabling Transparency in the Circular Economy to Validate Material Loops​

Figure 2​

Business Value​

Use Case / Domain​

Material Accounting in Catena-X​

Figure 3​

Secondary Material Content​

Introduction​

Business Context​

Use Case / Domain Explanation​

Figure 4​

Semantic Models​

Figure 5​

A. Introduction to the Semantic Models​

1. Material​

Optional Information, such as Reutilization​

Figure 6​

2. Order Data​

B. Accounting for Chain of Custody Models​

Figure 7​

Guiding Principles​

C. Calculation Logic for SMC​

1. Pre-consumer material content​

2. Post-consumer material content​

3. Optional: Reutilization content​

SMC and SMQ Calculation​

Figure 8​

D. Data Models and Github​

End of Life / Dismantling Services​

Introduction​

Closing Loops, Preserving Resources: Creating tomorrow's EoL landscape and empower the circularity​

Business Context​

Data Journey "End-of-Life"​

Figure 9​

User Journey "Certificate of Decomissioning"​

Figure 10​

Data Model and GitHub​

CE-Assistant​

Introduction​

Empowering Circular Economy Decisions: Introducing the Circular Strategy Assistant​

Business Context​

Use Case / Domain Explanation​

Figure 11​

Whitepaper​

End-of-life decision support to enable circular economy in the automotive industry based on digital twin data​

Empowering End-of-Life Vehicle Decision Making with Cross-Company Data Exchange and Data Sovereignty via Catena-X​

Digital Twins for Circular Economy - Enabling Decision Support for R-Strategies​

Logic / Schema​

Figure 12​

Secondary Marketplace​

Introduction​

Business Context​

User Journey and Architecture Overview​

Figure 13​

Figure 14​

Semantic Models​

Glossary​

NOTICE​

Circularity KIT

Vision & Mission

Introduction

Vision

Mission

Business Context

Circularity KIT Wheel

Figure 1

Use Case / Domain Explanation

Material Accounting

Introduction

Material Accounting: Enabling Transparency in the Circular Economy to Validate Material Loops

Figure 2

Business Value

Use Case / Domain

Material Accounting in Catena-X

Figure 3

Secondary Material Content

Introduction

Business Context

Use Case / Domain Explanation

Figure 4

Semantic Models

Figure 5

A. Introduction to the Semantic Models

1. Material

Optional Information, such as Reutilization

Figure 6

2. Order Data

B. Accounting for Chain of Custody Models

Figure 7

Guiding Principles

C. Calculation Logic for SMC

1. Pre-consumer material content

2. Post-consumer material content

3. Optional: Reutilization content

SMC and SMQ Calculation

Figure 8

D. Data Models and Github

End of Life / Dismantling Services

Introduction

Closing Loops, Preserving Resources: Creating tomorrow's EoL landscape and empower the circularity

Business Context

Data Journey "End-of-Life"

Figure 9

User Journey "Certificate of Decomissioning"

Figure 10

Data Model and GitHub

CE-Assistant

Introduction

Empowering Circular Economy Decisions: Introducing the Circular Strategy Assistant

Business Context

Use Case / Domain Explanation

Figure 11

Whitepaper

End-of-life decision support to enable circular economy in the automotive industry based on digital twin data

Empowering End-of-Life Vehicle Decision Making with Cross-Company Data Exchange and Data Sovereignty via Catena-X

Digital Twins for Circular Economy - Enabling Decision Support for R-Strategies

Logic / Schema

Figure 12

Secondary Marketplace

Introduction

Business Context

User Journey and Architecture Overview

Figure 13

Figure 14

Semantic Models

Glossary

NOTICE