Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality
It is promising to apply model predictive control (MPC) scheme to demand-controlled ventilation (DCV) for the energy-efficient provision of indoor air quality (IAQ). However, the application of MPC in actual multi-zone DCV systems is challenged by the complexity of the ventilation duct network as we...
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sg-ntu-dr.10356-1618852022-09-23T02:19:33Z Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality Li, Bingxu Wu, Bingjie Peng, Yelun Cai, Wenjian School of Electrical and Electronic Engineering Interdisciplinary Graduate School (IGS) Energy Research Institute @ NTU (ERI@N) SJ-NTU Corporate Lab Engineering::Electrical and electronic engineering Demand-Controlled Ventilation Robust Model Predictive Control It is promising to apply model predictive control (MPC) scheme to demand-controlled ventilation (DCV) for the energy-efficient provision of indoor air quality (IAQ). However, the application of MPC in actual multi-zone DCV systems is challenged by the complexity of the ventilation duct network as well as the difficulty in handling uncertainties in actual systems. To tackle these issues, we proposed a novel robust model predictive control (MPC) strategy for multi-zone DCV systems. First, a data-driven model is established for ventilation duct network to represent relationships between airflow and damper angles. Then, with the above model and zone IAQ dynamics models, a two-layer tube-based MPC scheme is designed to efficiently handle uncertainties in actual systems: the first-layer MPC generates nominal state trajectories based on nominal systems without uncertainties while the second-layer MPC generates control actions to direct states of actual uncertain system to nominal trajectories. With the proposed strategy, the optimal trajectories of damper angles and fan pressure can be determined to minimize energy consumption while maintaining satisfying IAQ in the presence of uncertainties. Experimental results show that, in the presence of uncertainties, the proposed strategy can reduce IAQ cost by 10% and energy consumption by 14% compared with the strategy adopting conventional feedback control scheme. When compared with the baseline strategy without optimization, the proposed strategy can reduce IAQ cost by 38% and energy consumption by 30%. In addition, the proposed strategy can provide flexible trade-off between energy-efficiency and robustness against uncertainties based on designers’ interest. Ministry of Education (MOE) This work was supported by the Ministry of Education, Singapore [Sponsor Award Number: RT07/19 (S)]. 2022-09-23T02:19:33Z 2022-09-23T02:19:33Z 2022 Journal Article Li, B., Wu, B., Peng, Y. & Cai, W. (2022). Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality. Applied Energy, 307, 118297-. https://dx.doi.org/10.1016/j.apenergy.2021.118297 0306-2619 https://hdl.handle.net/10356/161885 10.1016/j.apenergy.2021.118297 2-s2.0-85120693802 307 118297 en RT07/19 (S) Applied Energy © 2021 Elsevier Ltd. All rights reserved. |
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Engineering::Electrical and electronic engineering Demand-Controlled Ventilation Robust Model Predictive Control Li, Bingxu Wu, Bingjie Peng, Yelun Cai, Wenjian Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| description |
It is promising to apply model predictive control (MPC) scheme to demand-controlled ventilation (DCV) for the energy-efficient provision of indoor air quality (IAQ). However, the application of MPC in actual multi-zone DCV systems is challenged by the complexity of the ventilation duct network as well as the difficulty in handling uncertainties in actual systems. To tackle these issues, we proposed a novel robust model predictive control (MPC) strategy for multi-zone DCV systems. First, a data-driven model is established for ventilation duct network to represent relationships between airflow and damper angles. Then, with the above model and zone IAQ dynamics models, a two-layer tube-based MPC scheme is designed to efficiently handle uncertainties in actual systems: the first-layer MPC generates nominal state trajectories based on nominal systems without uncertainties while the second-layer MPC generates control actions to direct states of actual uncertain system to nominal trajectories. With the proposed strategy, the optimal trajectories of damper angles and fan pressure can be determined to minimize energy consumption while maintaining satisfying IAQ in the presence of uncertainties. Experimental results show that, in the presence of uncertainties, the proposed strategy can reduce IAQ cost by 10% and energy consumption by 14% compared with the strategy adopting conventional feedback control scheme. When compared with the baseline strategy without optimization, the proposed strategy can reduce IAQ cost by 38% and energy consumption by 30%. In addition, the proposed strategy can provide flexible trade-off between energy-efficiency and robustness against uncertainties based on designers’ interest. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Li, Bingxu Wu, Bingjie Peng, Yelun Cai, Wenjian |
| format |
Article |
| author |
Li, Bingxu Wu, Bingjie Peng, Yelun Cai, Wenjian |
| author_sort |
Li, Bingxu |
| title |
Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| title_short |
Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| title_full |
Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| title_fullStr |
Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| title_full_unstemmed |
Tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| title_sort |
tube-based robust model predictive control of multi-zone demand-controlled ventilation systems for energy saving and indoor air quality |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/161885 |
| _version_ |
1745574666579214336 |