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Business View

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The following page offers a high level business view on the Industry Core KIT with its vision, mission, benefits, business value, customer journey and examples in form of videos.

Vision & Mission

Vision

The goal of Catena-X is to empower data-driven use cases to address the current challenges of sustainability, resiliency, and quality. In the automotive industry, these challenges predominantly revolve around optimizing physical parts, components, and materials. The Catena-X Industry Core describes how these parts and vehicles can be digitally represented and found in the Catena-X network. It serves as the foundation to enable the seamless integration of multiple use cases. Reusing central components and standards (especially data provisioning of digital twins of parts) across different use cases promotes efficiency and interoperability. The Industry Core enables a sovereign data exchange based on parts and vehicles and lays the foundation for compliance with supply chain regulations. Each partner in each Industry Core compliant use case expands the Catena-X network and the realization of seamless data chains. As a result, cross-domain network effects and n-tier use cases become possible with each use case benefiting from all others.

Mission

The Industry Core describes a physical part, component or material at type and/or instance level, makes it identifiable and discoverable in the network and enables traversing across several levels.

Thus, it acts as a fundamental framework that facilitates smooth integration of various use cases. The Industry Core KIT and standards will enable data- and application-providers to instantiate and make use of the Industry Core. It will provide a common set of tools and a foundational definition to ensure that interoperability standards extend beyond technical aspects. This includes guidance for setting up the core- and enablement-services to ensure easy onboarding like guidance on setting up the required participant infrastructure like a decentralised Digital Twin Registry and Submodel endpoints for discovery of digital twins. Once set up, Catena-X use cases like Traceability, Circular Economy, PCF and more can easily be built on top by adding further business logic and aspect models to the digital twins established.

In the current version, the KIT supports the creation of digital twins on a Type-level (part- / material-number, catalog part) and Instance-level (a specific vehicle, serialized part, batches etc.) as well as the logical linking to their sub-components (Bill of Material, BoM). The default visibility of digital twins and their respective semantic models follows the one-up/one-down principle. This one-up / one-down relationship is the basis for a secure and data sovereign data chain.

DataChain_oneUp_OneDown

Parts and vehicles on the Instance-level can be provided and linked to their sub parts, when the part or vehicle has been built. This is why it is often also referred to the lifecycle phase BoM as built. Parts and vehicles at type level can be provided at the earliest when the part has been designed and is available for ordering as a catalog part. The linking of subcomponents at this point in time is often referred to as BoM as planned. However, the digital representation of the part at type level can also be initiated at a later point in time and remains in place until the part is dismantled.

Type_Levels

The Industry Core KIT provides the necessary standards, aspect models, APIs, logics, and processes on how to implement the Industry Core. All described specifications in the KIT are based on Catena-X standards like Data Space Connector, Asset Administration Shell (AAS), and decentralised Digital Twin Registry (DTR). They refer to other Catena-X KITs like the Connector KIT (EDC), Data Chain KIT (Item Relation Ship, IRS) and Business Partner KIT to ensure interoperability and data sovereignty according to IDSA and Gaia-X principles.

Type_Levels

Business Value & Benefits

Business Value

The Industry Core enables a sovereign data exchange based on parts and vehicles and the realization of n-tier data chains. It facilitates the implementation of part-related Catena-X use cases such as traceability, circular economy, PCF and many more.

The reusing core- & enablement services and the uniform usage of digital twins accelerates data providers and consumers to implement new use cases to the Catena-X ecosystem. This leads to a much faster time-to-market and scalability of new value-driven use cases.

Todays Challenge

Catena-X use cases and solutions are based on the provision and utilisation of data. To this end, the use cases often define their own infrastructure and semantics for data exchange. This leads to redundancies at data level, resulting in additional effort and complexity in data provision.

The Catena-X network and the Industry Core create an industry-wide standard for data exchange by re-using central components and shared semantics. To do so, once is enough: Once EDC, BPN, decentralized registry, and digital twins according to standardized semantics are established, numerous use cases can be enabled by extending the tech-stack with domain specific data aspects / models. The goal is to facilitate simple onboarding and leverage network effects. Reusing central components and standards (especially in data provisioning) across different use cases promotes efficiency and interoperability.

Benefits for OEM, SME and Solution Provider

OEM

The Industry Core simplifies data provision. Once the Industry Core is set up, multiple use cases can be easily enabled through additional sub-models attached to the digital twin, promoting component reuse. This reduces infrastructure costs and time to value, lowering the barrier to entry for participation in new use cases.

The same applies as a data consumer. Easy and fast discovery of supplier components enables fast and component-related data exchange. The pattern for access and interaction with data from business partners becomes independent of the data’s content: After all, additional use-cases can be onboarded simply by accessing different submodels of a digital twin.

SME

Reduced complexity helps SMEs participating at more than one Catena-X use case. One example is the reduction in interfaces to shopfloor, PLM or MES systems, as this data only needs to be provided once and not individually for each use case.

Solution Provider

Fast and efficient scalability of new use cases through reusability of central components. Solution providers will be able to implement and offer new Catena-X use cases easily and fast since they are built on top of each other.

Customer Journey

With the Industry Core KIT, we support the Catena-X customer journey for our adopters and solutions providers.

Customer Journey

Data Requirements

Bill of Material (BoM)

A bill of material resembles the structure of an end product. It is a list of all raw materials, sub-assemblies and sub-components that are needed to manufacture the end product. At Catena-X Industry Core we consider more than one single BoM. The BoM changes during the lifecyle and therefore, we are talking about different BoMs in different lifecycles.

BoM Representations

Single-Level BOM

A single-level BOM represents one level of an assembly and does not include any lower-level subassemblies.

Multi-Level BOM

A Multi-Level Bill of Materials (BOM) is a bill of materials (BOM) that lists the components, assemblies, and materials required to make a part. It provides a display of all components that are directly or indirectly used in a parent item. When an item is a subcomponent, blend, intermediate, etc., all of its components, including purchased parts and raw materials, are also exhibited. A multilevel structure can be illustrated by a tree with several levels. A multi-level BOM is created by connecting a series of individual single level BOMs together.

Flattened BOM

Flattening BOM means the intermediate levels in the BOM are removed and the lowest level is directly connected to the highest level.

BoM Lifecycle Stages

BoM LifeCycleStage concept based on STEP AP242 with slight adoptions in layout & wording:

  • Each instance can be identified by unique (within the organization) serial number (SN).
  • The ‘multi-SN’ (multi Serial number) describes product defined with a generic part or item
  • The ‘one per SN’ (one per Serial number) describes product defined with an individual part or item
NameIdentifier StepImplemented CXIdentifier CXDescriptionPurposeCreating time of BoMBoM Ausprägungenone/more fix suppliers
AsDesigned (AsDeveloped)multi-SNCurrently Not ImplementedPart number*
may not be the specific part number but a code that describes a part
(technische Produktbeschreibung)
BoM asDesigned is generated in the design phase of a new product including alternative parts.Build up the initial BoM in design phase of a new automotive product including alternative parts
Expected to have research & development part descriptions instead of specific part numbers
starting 2 years before SoP (for e.g. of a new vehicle project)150% incl. variants which will not be used laterpartly known
can be open at this point of time
AsPlannedmulti-SNImplementedPart numberBoM AsPlanned is used to plan the manufacturing process including alternative parts.BoM AsPlanned is used to plan manufacturing including alternative parts.
Sourcing will most likely be based on this (besides key parts which start earlier)
starting 1,5 years before building the first component120% of all variants are covered, incl. possibly multiple suppliers for the same componentfixed suppliers, could be more than one supplier per part
AsBuiltone per SNImplementedSerial number / batch numberBoM AsBuilt describes a product as manufactured.BoM as a component is built or manufactured.
During manufactoring of for e.g. a vehicle the serial numbers & batch numbers are documented (German: Verbaudokumentation).
This leads to one BoM per built car
during building process or directly after finishing100%one specific supplier
AsMaintainedone per SNCurrently Not ImplementedSerial number / batch numberBoM AsMaintained describes the product after purchasing by a customer and updates by maintenance.BoM after for e.g. a vehicle was picked up by the customer. Changes to live cycle before may apply due to maintenance or repair work e.g. exchange of parts, liquids, ...Starts when customer has picked up the product, updating if any change is done100% inkl. replaced parts, incl. history of exchanged partsone specific supplier

The lifecycle phases are mapped exclusively via the corresponding aspect models, which are based on the DataChainTemplate. These are the aspect models starting with the prefixes 'SingleLevelBom' or 'SingleLevelUsage'.

While the aspect models with the prefix 'SingleLevelBoM' represents one sub-level of an assembly and does not include any lower-level subassemblies, the aspect models with the prefix 'SingleLevelUsage' contain the information in which parent part(s)/product(s) the given item is assembled in.

The following examples illustrate the corresponding logic:

  • SingleLevelBoMAsPlanned
  • SingleLevelUsageAsMaintained (not yet implemented, but to illustrate the logic).

All other aspect models, such as SerialPart, do not refer to a life cycle but exclusively to a specific type of digital twin, such as a type of digital twin, such as PartInstance or PartType.

Two of the considered BoMs are already implemented in the Industry Core and will be described as follows.

AsPlanned

Short Introduction: What is a BoM AsPlanned?

The BoM AsPlanned is the generic list of all possible catalogue parts & materials for a specific vehicle project and the supply chain from OEM to raw material suppliers. The BoM is also called 120% which means that it includes alternative parts / materials (e.g. LED headlights and XENON headlights) and parts for certain markets. It will be set up way before Start of Production (SOP) and be updated if the contents are updated. It is used for Sourcing / Production Planning and always reflects the current state of parts / materials build into this specific vehicle project.

The BoM AsPlanned also includes all versions of parts like changed parts. It has to enable parts/materials provided from multiple manufacturers or the same manufacturer at different production sites. Additionally it must be possible to map relations of the same part/material to different customers.

The BoM AsPlanned is based on the concept of the digital twin PartType. The corresponding life cycle is mapped using the aspect models SingleLevelBoMAsPlanned and SingleLevelUsageAsPlanned.

The complexity of generic is much higher than BoM AsBuilt. It is used for technical topics, e.g., Supply Chain Act, DCM.

AsBuilt

Short Introduction: What is a BoM AsBuilt?

A BoM AsBuilt resembles a single vehicle, which means that each vehicle built has its own individual BoM asBuilt. The BoM includes all part/components which either have a serial number, batch number, JIS number (sequence number) or a combination out of these. This means, that there is a direct and specific connection between a parent and a child part/component so that an accurate and exact traceability is possible.

Also, the BoM is called 100%, as there are no alternative parts included but only built parts. Therefore, it will be set up when a part is produced and can be connected to its parent and child parts.

The BoM AsBuilt is based on the concept of the digital twin PartInstance. The corresponding life cycle is mapped using the aspect models SingleLevelBoMAsBuilt and SingleLevelUsageAsBuilt.

In Catena-X the BoM asBuilt is used for technical topics, e.g., Quality, Battery Passport (CE).

NOTICE

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

  • SPDX-License-Identifier: CC-BY-4.0
  • SPDX-FileCopyrightText: 2023 BASF SE
  • SPDX-FileCopyrightText: 2023 Bayerische Motoren Werke Aktiengesellschaft (BMW AG)
  • SPDX-FileCopyrightText: 2023 Fraunhofer-Gesellschaft zur Foerderung der angewandten Forschung e.V. (represented by Fraunhofer ISST & Fraunhofer IML)
  • SPDX-FileCopyrightText: 2023 German Edge Cloud GmbH & Co. KG
  • SPDX-FileCopyrightText: 2023 Mercedes Benz AG
  • SPDX-FileCopyrightText: 2023 Robert Bosch Manufacturing Solutions GmbH
  • SPDX-FileCopyrightText: 2023 SAP SE
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  • SPDX-FileCopyrightText: 2023 T-Systems International GmbH
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  • SPDX-FileCopyrightText: 2023 Contributors to the Eclipse Foundation
  • Source URL: https://github.com/eclipse-tractusx/eclipse-tractusx.github.io/tree/main/docs-kits/kits/Industry%20Core%20Kit (latest version)