A Four-Layer Digital Framework for BIM and FM Integration in a Sustainable Urban Drainage System †
Faculty of Civil Engineering, VŠB—Technical University of Ostrava, 70800 Ostrava, Czech Republic
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Author to whom correspondence should be addressed.
†
Presented at the 5th International Conference on Advances in Environmental Engineering, Ostrava, Czech Republic, 26–28 November 2025.
Eng. Proc. 2025, 116(1), 39; https://doi.org/10.3390/engproc2025116039
Published: 18 December 2025
Abstract
This paper introduces a digital framework that integrates Building Information Modeling (BIM) and Facility Management (FM) to enhance the lifecycle performance of Sustainable Urban Drainage Systems (SuDS). Addressing the limitations of traditional drainage such as poor resilience and fragmented maintenance, the framework consists of the following four layers: BIM-based 3D asset modeling, sensor-driven monitoring, FM-integrated operations, and climate-informed adaptive planning. Grounded in systems engineering and aligned with International Standard ISO 19650 standards, it enables a dynamic digital twin to support continuous feedback and predictive maintenance. Illustrated through diagrams and comparison, the framework promotes adaptability and long-term sustainability in urban water infrastructure.
1. Introduction
Urban flooding, intensified by climate change and accelerated land-surface sealing, presents a significant challenge for contemporary urban environments. Sustainable Drainage Systems (SuDSs) provide a decentralized and ecologically adaptive alternative to traditional piped drainage infrastructure by promoting surface water attenuation, infiltration, and treatment through natural processes [1]. These systems are designed to mimic natural hydrological functions and enhance urban resilience. Empirical analyses indicate that a substantial proportion of Sustainable Drainage Systems (SuDS) exhibit declining performance within a few years post-implementation, a trend largely attributed to inconsistent maintenance protocols and the lack of real-time monitoring systems [2].
Emerging digital technologies such as Building Information Modeling (BIM) and Facility Management (FM) systems hold substantial promise for improving the lifecycle performance of SuDS infrastructure. BIM provides structured visualization, data integration, and simulation capabilities, while FM platforms support routine operations and maintenance workflows. Yet, the integration of BIM and FM within the context of SuDS remains limited and underexplored in current practice [3,4,5].
This study proposes a four-layer digital framework to bridge this gap and support the performance of SuDS assets.
2. Literature Review
2.1. SuDS Challenges in Urban Environments
Sustainable Drainage Systems (SuDSs) components, such as bioswales, infiltration basins, and permeable pavements, provide ecologically effective solutions for managing urban runoff. However, their spatially distributed nature presents ongoing challenges for asset tracking and performance management. In the absence of a centralized digital asset register or real-time condition monitoring mechanisms, deterioration often remains undetected until system failures emerge [2,6]. Empirical findings from urban projects demonstrate a persistent dependence on manual inspection routines, which are both labor-intensive and subject to variability [6]. Moreover, SuDS designs frequently fail to incorporate feedback from operational performance, limiting adaptive improvements and resulting in recurring inefficiencies and weak institutional loops [3].
2.2. BIM and FM in Water Infrastructure
BIM tools generate comprehensive 3D parametric representations of infrastructure assets, facilitating hydrological modeling, construction sequencing, and strategic maintenance planning [2]. Concurrently, FM systems are responsible for capturing and processing operational data, including work orders, inspection records, and condition assessments [4]. Integrating BIM and FM platforms enables the creation of a digital twin as a synchronized virtual model that mirrors both the physical characteristics and real-time operational status of infrastructure components. In the context of urban stormwater management, such BIM and FM integration, particularly when coupled with sensor networks, has demonstrated measurable gains in efficiency, responsiveness, and system resilience.
3. The Four-Layer Digital Framework
The proposed BIM–FM–SuDS framework is organized into four integrated functional layers, each layer addresses a discrete system function: modeling, sensing, managing, and adapting. This is aligned with ISO 19650-compliant BIM workflows. A digital twin needs the following [4]:
- Physical Model;
- Sensor Feedback;
- Decision Engine;
- Environmental Context.
The overall structure of the proposed four-layer integration approach is illustrated in Figure 1.
3.1. Layer 1: BIM-Based SuDS Modeling
This foundational layer involves 3D modeling of SuDS components using Industry Foundation Classes (IFCs) classifications within compliant BIM tools. Features such as soil infiltration rate, vegetation type, and hydraulic properties are embedded in the model. Geographic Information System (GIS) integration enables large-scale mapping of urban catchments.
3.2. Layer 2: Sensor-Based Monitoring
Internet of Things (IoT)-enabled sensors collect real-time data on water levels, soil moisture, and flow rates. This data feeds directly into the BIM model, establishing a digital twin that supports failure prediction and condition-based maintenance.
3.3. Layer 3: Facility Management Integration
FM systems use sensor inputs to manage inspections, generate maintenance schedules, and trigger alerts. Beyond routine operational tasks, this layer establishes a continuous data feedback mechanism that updates and refines the BIM environment. As-built conditions, maintenance histories, vegetation health assessments, infiltration performance, and hydraulic behavior observations are systematically synchronized back into the BIM model. This bidirectional exchange transforms the BIM environment from a static design representation into a living operational database, ensuring that the digital twin evolves in parallel with real-world asset conditions. Such dynamic updating is essential for enabling predictive analytics, optimizing maintenance strategies, and supporting long-term lifecycle planning for SuDS infrastructure.
3.4. Layer 4: Climate Adaptation Feedback
The final layer integrates external datasets—such as updated rainfall projections and land-use maps—to inform adaptive design adjustments. This ensures that the SuDS system remains robust in the face of climate change and urban expansion.
The lifecycle integration of SuDS within the digital twin environment is illustrated in Figure 2.
Field observations from case studies across Europe and Asia demonstrated that adding more than four layers introduced redundancy without delivering additional value. Therefore, the four-layer structure offers a functionally complete yet streamlined solution.
The comparative assessment of traditional and BIM–FM–SuDS management approaches is summarized in Table 1.
4. Discussion
The four-layer framework delivers several key benefits:
- Lifecycle Optimization: Enables complete visibility from design through maintenance and adaptation.
- Centralized Data Management: Merges design, operational, and environmental data into one system.
- Predictive Maintenance: Real-time monitoring informs proactive interventions.
- Resilience and Adaptability: Dynamic adaptation to changing climatic and urban conditions.
Despite these benefits, challenges such as high sensor installation costs, FM system complexity, and interoperability issues must be addressed. Solutions include prioritizing high-risk areas, training for FM tools, and adopting open standards like IFC.
Future work may explore integration with AI-based flood prediction, community-driven sensor inputs, and national digital infrastructure policies.
5. Conclusions
This study presents a robust digital framework that integrates BIM and FM technologies to enhance the design, monitoring, and adaptation of SuDS. Each of the four layers plays a vital role in transitioning SuDS from static systems to intelligent, adaptive infrastructure. Cities striving for resilience must adopt such digital paradigms to address the growing challenges posed by urbanization and climate variability.
Author Contributions
Conceptualization, T.L.P. and E.W.; methodology, T.L.P.; formal analysis, T.L.P.; writing—original draft preparation, T.L.P.; writing—review and editing, E.W.; visualization, T.L.P.; supervision, E.W. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
No new data were created or analyzed in this study. Data sharing is not applicable to this article.
Conflicts of Interest
The authors declare no conflicts of interest.
References
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Figure 1.
BIM–FM–SuDS integration framework diagram.
Figure 2.
SuDS lifecycle with digital twin integration.
Table 1.
Comparison of traditional vs. BIM–FM–SuDS management.
| Aspect | Traditional SuDS | BIM–FM–SuDS Integration |
|---|---|---|
| Asset Visibility | Fragmented, paper-based asset records | Centralized 3D digital models with rich metadata |
| Maintenance Strategy | Reactive (typically post-failure) | Proactive, using predictive analytics and alerts |
| Monitoring Method | Manual, periodic inspections | Continuous, sensor-driven performance tracking |
| Design Responsiveness | Limited feedback, anecdotal adjustments | Data-informed, scenario-driven design updates |
| Compliance Reporting | Static, infrequent documentation | Dynamic, real-time digital dashboards |
| Climate Adaptability | Low resilience and poor responsiveness | Flexible through simulation and real-time updates |
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MDPI and ACS Style
Pham, T.L.; Wernerová, E. A Four-Layer Digital Framework for BIM and FM Integration in a Sustainable Urban Drainage System. Eng. Proc. 2025, 116, 39. https://doi.org/10.3390/engproc2025116039
AMA Style
Pham TL, Wernerová E. A Four-Layer Digital Framework for BIM and FM Integration in a Sustainable Urban Drainage System. Engineering Proceedings. 2025; 116(1):39. https://doi.org/10.3390/engproc2025116039
Chicago/Turabian StylePham, Thanh Luat, and Eva Wernerová. 2025. "A Four-Layer Digital Framework for BIM and FM Integration in a Sustainable Urban Drainage System" Engineering Proceedings 116, no. 1: 39. https://doi.org/10.3390/engproc2025116039
APA StylePham, T. L., & Wernerová, E. (2025). A Four-Layer Digital Framework for BIM and FM Integration in a Sustainable Urban Drainage System. Engineering Proceedings, 116(1), 39. https://doi.org/10.3390/engproc2025116039
