Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number

Certain manufacturing or industrial processes may involve variable conditions, and intentionally transient boiler operation allows optimal adaptation to these variations. This helps maintain efficiency and reduce energy consumption during different process phases. Transient operation is inherent dur...

Full description

Bibliographic Details
Published in:Chemical Product and Process Modeling
Main Author: Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
Format: Article
Language:English
Published: Walter de Gruyter GmbH 2024
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85205352859&doi=10.1515%2fcppm-2024-0018&partnerID=40&md5=bc15e5417095a03e0992bc8deb951b27
id 2-s2.0-85205352859
spelling 2-s2.0-85205352859
Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
2024
Chemical Product and Process Modeling


10.1515/cppm-2024-0018
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85205352859&doi=10.1515%2fcppm-2024-0018&partnerID=40&md5=bc15e5417095a03e0992bc8deb951b27
Certain manufacturing or industrial processes may involve variable conditions, and intentionally transient boiler operation allows optimal adaptation to these variations. This helps maintain efficiency and reduce energy consumption during different process phases. Transient operation is inherent during the start-up and intermittent phases in reaching the pressure required for boiler operation. Optimizing these transient states can reduce energy consumption. Dynamic optimization of boilers is crucial for several reasons, especially in industrial and power generation settings. Boilers are used to produce steam or hot water for various processes, and optimizing their performance can lead to increased efficiency, reduced energy consumption, and improved overall system reliability. The dynamic optimization problems were solved using the orthogonal collocation method. Three problem optimizations were considered in this study: minimize process time (P1), minimize energy consumption without optimized final time (P2), minimize energy consumption with optimized final time (P3). The control/decision variables applied were firing rate, Q, and water feed flowrate, qf. From the simulation results, the control trajectories of P3 were chosen to be the most effective control operation to achieve the minimum energy consumption for reaching target pressure, i.e., 10.2 MPa, with a reasonable intermittent unit time. In practice, the selection of the number of intervals is often determined through a combination of domain knowledge, computational resources, and the desired level of accuracy. Sensitivity analysis and testing with different interval sizes can help in understanding the impact of this parameter on the optimization results. A greater interval time will decrease energy consumption. © 2024 Walter de Gruyter GmbH, Berlin/Boston 2024.
Walter de Gruyter GmbH
19342659
English
Article

author Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
spellingShingle Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
author_facet Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
author_sort Rohman F.S.; Wan Alwi S.R.; Azmi A.; Er H.A.; Ahmad Termizi S.N.A.
title Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
title_short Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
title_full Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
title_fullStr Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
title_full_unstemmed Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
title_sort Dynamic optimization of boiler for minimizing energy consumption in the intentionally transient process operation: Effect of different interval number
publishDate 2024
container_title Chemical Product and Process Modeling
container_volume
container_issue
doi_str_mv 10.1515/cppm-2024-0018
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85205352859&doi=10.1515%2fcppm-2024-0018&partnerID=40&md5=bc15e5417095a03e0992bc8deb951b27
description Certain manufacturing or industrial processes may involve variable conditions, and intentionally transient boiler operation allows optimal adaptation to these variations. This helps maintain efficiency and reduce energy consumption during different process phases. Transient operation is inherent during the start-up and intermittent phases in reaching the pressure required for boiler operation. Optimizing these transient states can reduce energy consumption. Dynamic optimization of boilers is crucial for several reasons, especially in industrial and power generation settings. Boilers are used to produce steam or hot water for various processes, and optimizing their performance can lead to increased efficiency, reduced energy consumption, and improved overall system reliability. The dynamic optimization problems were solved using the orthogonal collocation method. Three problem optimizations were considered in this study: minimize process time (P1), minimize energy consumption without optimized final time (P2), minimize energy consumption with optimized final time (P3). The control/decision variables applied were firing rate, Q, and water feed flowrate, qf. From the simulation results, the control trajectories of P3 were chosen to be the most effective control operation to achieve the minimum energy consumption for reaching target pressure, i.e., 10.2 MPa, with a reasonable intermittent unit time. In practice, the selection of the number of intervals is often determined through a combination of domain knowledge, computational resources, and the desired level of accuracy. Sensitivity analysis and testing with different interval sizes can help in understanding the impact of this parameter on the optimization results. A greater interval time will decrease energy consumption. © 2024 Walter de Gruyter GmbH, Berlin/Boston 2024.
publisher Walter de Gruyter GmbH
issn 19342659
language English
format Article
accesstype
record_format scopus
collection Scopus
_version_ 1814778502474366976