The DOR ontology focuses on capturing information related to the decommissioning processes of buildings and the subsequent reuse of building materials, components or even functional layers. It enables stakeholders to plan and execute efficient and sustainable deconstruction and post-consumer practices. The DOR ontology is developed with a trans-perspective vision, recognising the diverse interpretations and perspectives associated with the concept of reusability among different stakeholders. The ontology aims to facilitate a circular future by providing a comprehensive and time-proof circular information exchange solution that acknowledges and incorporates this inherent variability.
The DOR ontology builds upon existing Linked Building Data ontologies such as Building Topology Ontology (BOT), Building Product Ontology (BPO), and Digital Construction Materials (DICM). By extending these established ontologies, DOR ensures compatibility and interoperability with other domain-specific knowledge models and applications.
Use Cases: The DOR ontology serves several important use cases in the built environment domain:
- Pre- and Post-Deconstruction Planning: Stakeholders can utilise the ontology to enrich their information models for pre- and post-deconstruction planning. It enables them to capture and organise relevant data, facilitating effective decision-making throughout the deconstruction process.
- Circular Databases: The ontology supports the exchange of information with circular databases. By providing a standardised representation of concepts and relationships, it enables seamless integration of data and knowledge sharing among stakeholders in the building deconstruction and material reuse community.
- Material Bank Management: DOR supports the processes involved in depositing or assessing the reclaimed components in a material bank. It includes concepts for digital diagnosis, conditions for proper inventory management or remanufacturing of components in a material bank for second life cycle reuse, and documentation requirements to make sure the next reuser has enough information to make the right decisions.
Classes The ontology includes the following classes:
- assembly
- Building
- Certification
- Chemical Connection
- Circular Potential
- Circular Requirement
- component connection
- Connection Type
- Designer
- Direct Connection
- Discard Potential
- element
- Exposure
- Facade
- Functional Layer
- Gravitational Connection
- Hazardous Material
- indirect connection
- Inspection
- Inspection Method
- Inspection Mode
- Intervention
- Legal Requirement
- Logistics
- Manufacturer
- Material
- Material Bank Agent
- Material Source Type
- Mechanical Connection
- Non-hazardous Material
- Non-renewable Material
- Off-site
- On-site
- Personnel
- Pre-Deconstruction Auditor
- Primary Raw Material
- product
- Recyclable Material
- Recycling Potential
- Remanufacturing Potential
- Renewable Material
- Repurposing Potential
- Reuse Potential
- Reversible Connection
- Secondary Raw Material
- Site Dependency
- Space Plan
- Structure
- Trained Personnel
- Untrained Personnel
Object Properties The ontology defines the following object properties:
- Audits For
- Designs For
- has Circular Potential
- has Circular Requirement
- has Connection Type
- has element
- has Final Circular Potential
- has Functional Layer
- has Material
- has Recommended Inspection
- has Recommended Inspection Method
- has Recommended Inspection Mode
- has Required Inspection
- has Required Inspection Method
- has Required Inspection Mode
- has Source Type
- Produces For
- Recertifies For
Data Properties The ontology includes the following data properties:
- has Circular Potential Indicator
- has Construction Date
- has Current Use Count
- has Decommissioning Date
- has Design Life
- has Economic Life
- has Remaining Reuse Count
- has Service Life
- has Total Reuse Count
- has Waste Code
This ontology is developed as a part of the PhD research study by Arghavan Akbarieh. Do not hesitate to reach out to me and have a chat about digital, circular construction.