Saved in:
Bibliographic Details
Main Authors: Byun, Ji-Eun, Lee, Se-Hyeok
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.03289
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917313769373696
author Byun, Ji-Eun
Lee, Se-Hyeok
author_facet Byun, Ji-Eun
Lee, Se-Hyeok
contents This study presents a new system performance function for process plant reliability analysis, formulated to capture both structural topology and process sequencing constraints. Built on a modified maximum-flow framework and solved via linear programming, the proposed function efficiently quantifies the maximum feasible flow through a series of interconnected stages. It addresses limitations of existing models, such as fault trees and event trees, that often overlook flow continuity and topological dependencies. The system function is integrated into a reliability assessment framework, enabling the evaluation of system failure probability and reliability-based component importance measures. Application to two benchmark examples, including a gas supply plant with 57 nodes and 102 edges, demonstrates the effectiveness of the proposed system function and the validity of the resulting reliability assessment for risk-informed layout planning. A reconfiguration guided by component importance measures yields up to a 20% reduction in system failure probability, underscoring the importance of effective equipment and pipeline layout. The proposed framework offers a promising direction for reliability-based management of industrial process facilities.
format Preprint
id arxiv_https___arxiv_org_abs_2603_03289
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A New System Function for Maximum Processable Flow in Process Plants and Application to Reliability Assessment
Byun, Ji-Eun
Lee, Se-Hyeok
Systems and Control
90B10, 90B25, 90C05
This study presents a new system performance function for process plant reliability analysis, formulated to capture both structural topology and process sequencing constraints. Built on a modified maximum-flow framework and solved via linear programming, the proposed function efficiently quantifies the maximum feasible flow through a series of interconnected stages. It addresses limitations of existing models, such as fault trees and event trees, that often overlook flow continuity and topological dependencies. The system function is integrated into a reliability assessment framework, enabling the evaluation of system failure probability and reliability-based component importance measures. Application to two benchmark examples, including a gas supply plant with 57 nodes and 102 edges, demonstrates the effectiveness of the proposed system function and the validity of the resulting reliability assessment for risk-informed layout planning. A reconfiguration guided by component importance measures yields up to a 20% reduction in system failure probability, underscoring the importance of effective equipment and pipeline layout. The proposed framework offers a promising direction for reliability-based management of industrial process facilities.
title A New System Function for Maximum Processable Flow in Process Plants and Application to Reliability Assessment
topic Systems and Control
90B10, 90B25, 90C05
url https://arxiv.org/abs/2603.03289