Generalizable occupant-driven optimization model for domestic hot water production in NZEB

Kazmi, Hussain; D’Oca, Simona; Delmastro, Chiara; Lodeweyckx, Stefan; Corgnati, Stefano Paolo

doi:10.1016/j.apenergy.2016.04.108

Cited by 66 publications

(40 citation statements)

References 34 publications

(34 reference statements)

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“…Both papers are relevant to this work, although here the scope is narrower: not the building but the solar DHW system alone. Kazmi et al [47] proposed a solution for this problem employing a set of tools including a hybrid reinforcement learning process, seasonal auto-regressive integrated mobile average (SARIMA) model, and a hybrid ant-colony optimization (hACO) algorithm. The paper contains useful remarks about thermal energy storage modelling.…”

Section: Applications Of Reinforced Learning To Energy Systemsmentioning

confidence: 99%

Analysis and Adaptation of Q-Learning Algorithm to Expert Controls of a Solar Domestic Hot Water System

Bettoni

Soppelsa

Fedrizzi

et al. 2019

ASI

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This paper discusses the development of a coupled Q-learning/fuzzy control algorithm to be applied to the control of solar domestic hot water systems. The controller brings the benefit of showing performance in line with the best reference controllers without the need for devoting time to modelling and simulations to tune its parameters before deployment. The performance of the proposed control algorithm was analysed in detail concerning the input membership function defining the fuzzy controller. The algorithm was compared to four standard reference control cases using three performance figures: the seasonal performance factor of the solar collectors, the seasonal performance factor of the system and the number of on/off cycles of the primary circulator. The work shows that the reinforced learning controller can find the best performing fuzzy controller within a family of controllers. It also shows how to increase the speed of the learning process by loading the controller with partial pre-existing information. The new controller performed significantly better than the best reference case with regard to the collectors’ performance factor (between 15% and 115%), and at the same time, to the number of on/off cycles of the primary circulator (1.2 per day down from 30 per day). Regarding the domestic hot water performance factor, the new controller performed about 11% worse than the best reference controller but greatly improved its on/off cycle figure (425 from 11,046). The decrease in performance was due to the choice of reward function, which was not selected for that purpose and it was blind to some of the factors influencing the system performance factor.

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Section: Applications Of Reinforced Learning To Energy Systemsmentioning

confidence: 99%

Analysis and Adaptation of Q-Learning Algorithm to Expert Controls of a Solar Domestic Hot Water System

Bettoni

Soppelsa

Fedrizzi

et al. 2019

ASI

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“…In the context of smart homes, this means agents which observe the state of the smart home, the building and the occupant and then reason about possible next actions which can then be executed (a practical example of such an approach appears in [20]). Model-based reinforcement learning includes an additional step, whereby the controller first learns a representation of the environment, which it then uses to reason about next actions (a practical example of such an approach appears in [21]). These differences are elaborated on in Fig.…”

Section: B Reinforcement Learningmentioning

confidence: 99%

“…The energy consumption can be for any end draw, e.g. for thermal conditioning of the building or to providing adequate lighting under all possible conditions [15], [18], [21]. It can also be extended to other use cases such as minimizing the amount of water being consumed by informing the user of any leaks or the fact that a dishwasher might save them additional water.…”

Section: A Smart Homes 1) Resource Efficiencymentioning

confidence: 99%

Smart Home Futures: Algorithmic Challenges and Opportunities

Kazmi¹,

Mehmood²,

Amayri³

2017

2017 14th International Symposium on Pervasive Systems, Algorithms and Networks &Amp; 2017 11th International Conference on Fro

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Humans are increasingly spending their time indoors. This, along with higher wealth levels and rise of internet of things, has provided designers and planners the opportunity to reimagine living spaces. Smart homes come in many different shapes, but to gain widespread acceptance they have to increase the utility of building occupants in some meaningful way. The most straightforward way of creating these smart homes is assumed to be through artificial intelligence. In this paper, we take a critical look at some algorithmic approaches that have been formulated to do so and the opportunities they will create in the short term. We also present some key challenges that must be overcome before these opportunities can be realized in practice.

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“…Although an increased efficiency of the primary equipment can decrease the amount of energy consumption in a hot water system, this decrease often creates a bottleneck in reality, when most of the equipment has been updated to achieve better efficiency . Most people tend to neglect the energy saving potential during an operation period, despite the fact that a significant amount of energy can still be saved.…”

Section: Introductionmentioning

confidence: 99%

“…12 Although an increased efficiency of the primary equipment can decrease the amount of energy consumption in a hot water system, this decrease often creates a bottleneck in reality, when most of the equipment has been updated to achieve better efficiency. 13 Most people tend to neglect the energy saving potential during an operation period, despite the fact that a significant amount of energy can still be saved. A study from the Netherlands revealed that if the occupants do not conduct their tasks in a highly efficient way, that is, one that supports the intended design, even a high-performance system can consume much more energy than expected.…”

Section: Introductionmentioning

confidence: 99%

Predictive control based on occupant behavior prediction for domestic hot water system using data mining algorithm

Cao

Hou

et al. 2019

Energy Science & Engineering

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Domestic hot water systems are a primary source of energy consumption in buildings, and present a promising future in terms of energy saving. Predictive control methods have been used to reduce energy consumption during an operation period. However, current methods lack consideration of occupant behavior, which significantly influences the prediction results. In this study, a data‐based predictive method is proposed to predict the shower behavior of occupants. A dataset was collected from seven occupants and was trained using support vector machine (SVM) to learn their showering habits. These results were used to predict the hot water demand. A comparative analysis shows that, in this way, the prediction results are more reliable under predictive control than predicting the hot water demand directly using SVM. A simulation of a domestic hot water system was then conducted. The results indicate that the proposed approach can reduce the heat loss from a hot water storage tank (ST) by up to 33% compared to a traditional control method, while maintaining a high assurance of the hot water supply (an insufficient hot water supply of less than 1%) with little change to the original system.

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Generalizable occupant-driven optimization model for domestic hot water production in NZEB

Cited by 66 publications

References 34 publications

Analysis and Adaptation of Q-Learning Algorithm to Expert Controls of a Solar Domestic Hot Water System

Analysis and Adaptation of Q-Learning Algorithm to Expert Controls of a Solar Domestic Hot Water System

Smart Home Futures: Algorithmic Challenges and Opportunities

Predictive control based on occupant behavior prediction for domestic hot water system using data mining algorithm

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