Optimal flow control of a forced circulation solar water heating system with energy storage units and connecting pipes

Ntsaluba, Sula B.K.; Zhu, Bing; Xia, Xiaohua

doi:10.1016/j.renene.2015.11.047

Cited by 43 publications

(8 citation statements)

References 33 publications

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“…The annual energy cost savings is the cumulative electrical energy generated by the PV module for the standard PV system, as well as the optimal switching control model. Furthermore, the heat gain within the hot water storage tank is included solely for the optimal switching control model, which is calculated using the following equation [50]:…”

Section: True Payback Period Analysismentioning

confidence: 99%

Optimal Switching Control of Flow in PV/T Systems with Forced Circulation: Model Development

2018

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Cooling the operating surface is a key operational factor to take into consideration to achieve higher efficiency when operating solar photovoltaic systems. Appropriate cooling may improve the electrical efficiency and decrease the rate of cell degradation with time, resulting in maximization of the life span of photovoltaic modules. The excessive heat removed by the cooling system can be used in domestic, commercial or industrial applications. The hybrid photovoltaic/thermal (PV/T) system cooled by forced water circulation is one of the most efficient methods used to improve the electrical performance of a PV module. These systems operate mostly on the principle in cooling the PV module at a constant flow rate. However, the optimal PV output power cannot be achieved due to the circulating water not absorbing most of the heat on the surface of the PV module. In order to solve this problem, a mathematical model dealing with the optimal switching of flow in PV/T systems with forced circulation has been developed, with the aim of controlling the surface operating temperature whilst increasing the conversion efficiency. The optimal switching control model is used to reduce the surface operating temperature of the PV module, where it is simulated by making use of the SCIP (Solving Constrained Integer Programs) solver in the optimization toolbox in MATLAB. The simulation results illustrate that the optimal switching control of flow may improve the electrical output power of a PV module, as well as effectively reducing the surface temperature thereof. Furthermore, an economic feasibility study was performed to compare these systems, where the optimal switching control strategy has a significantly higher initial capital cost compared to the standard PV system. However, when studying both systems over their predicted lifetime, the optimal switching control strategy generates a significantly higher profit, regardless of its extortionate initial capital cost, and is, therefore, the ultimately efficient system.

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Section: True Payback Period Analysismentioning

confidence: 99%

Optimal Switching Control of Flow in PV/T Systems with Forced Circulation: Model Development

2018

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“…Optimization has been performed by calculating the root of the active power equation (ma, ) and reactive power equation (ma, ) using Newton Raphson method. In 2016, Ntsaluba et al [90] presented a flow-rate optimization of solar water heating system (SWHS) with specific focus placed on pump flow-rate optimization. In 2015, Wang et al [91] presented an approach to analyse the optimal capacity and economic feasibility of a hybrid energy storage system (HESS) supporting the dispatch of a 30 MW photovoltaic (PV) power plant.…”

Section: 2mentioning

confidence: 99%

Optimal Power Flow Techniques under Characterization of Conventional and Renewable Energy Sources: A Comprehensive Analysis

Khan

Singh

2017

Journal of Engineering

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The exhaustive knowledge of optimal power flow (OPF) methods is critical for proper system operation and planning, since OPF methods are utilized for finding the optimal state of any system under system constraint conditions, such as loss minimization, reactive power limits, thermal limits of transmission lines, and reactive power optimization. Incorporating renewable energy sources optimized the power flow of system under different constraints. This work presents a comprehensive study of optimal power flows methods with conventional and renewable energy constraints. Additionally, this work presents a progress of optimal power flow solution from its beginning to its present form. Authors classify the optimal power flow methods under different constraints condition of conventional and renewable energy sources. The current and future applications of optimal power flow programs in smart system planning, operations, sensitivity calculation, and control are presented. This study will help the engineers and researchers to optimize power flow with conventional and renewable energy sources.

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“…Well-established techniques developed in 1970s-1980s, such as on-off ("bang-bang") or modulating ("differential") control, are usually implemented in commercial controllers. Refinements of proportional control are proposed in [26], and complex algorithms are more and more commonly found in the literature, for example using optimal control to determine the correct primary flow rates to maximize energy gain, whilst meeting user-defined tank temperatures with minimum energy usage in the secondary loop of the system [27]. Valdiserri [28] includes on-off control in the TRNSYS simulation of solar water heating systems located in seven European cities, analyzing the effect of night switch-offs.…”

Section: Introductionmentioning

confidence: 99%

A Standard-Based Method to Simulate the Behavior of Thermal Solar Systems with a Stratified Storage Tank

Piana

Grassi

Socal³

2020

Energies

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Thermal solar systems are interesting solutions to reduce CO 2 emissions and gradually promote the use of renewable sources. However, sizing such systems and analysing their behavior are still challenging issues, especially for the trade-off between useful solar energy maximization and stagnation risk minimization. The new EPB (Energy Performance of Buildings) standard EN 15316-4-3:2017 offers several methods to evaluate the performance of a forced circulation solar system. One of them is a dynamic hourly method that must be used together with EN 15316-5:2017 for the simulation of the stratified storage tank connected with the solar loop. In this work, such dynamic hourly method is extended to provide more realistic predictions. In particular, modeling of the pump operation due to solar fluid temperature exceeding a set threshold, or due to low temperature differential between solar field and storage tank, is introduced as an on–off control. The implemented code is applied to a case study of solar system for the preparation of domestic hot water and the impact of different design parameters is evaluated. The model predicts a higher risk of overtemperature lock-out or stagnation when the solar field surface is increased, the storage volume is reduced and water consumption is set to zero to simulate summer vacation periods. Finally, a simple modulating control with a time step of a few seconds to a few minutes is introduced, quantitatively showing the resulting benefits in terms of useful solar energy increase, back-up operation savings and reduced auxiliary energy use.

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Optimal flow control of a forced circulation solar water heating system with energy storage units and connecting pipes

Cited by 43 publications

References 33 publications

Optimal Switching Control of Flow in PV/T Systems with Forced Circulation: Model Development

Optimal Switching Control of Flow in PV/T Systems with Forced Circulation: Model Development

Optimal Power Flow Techniques under Characterization of Conventional and Renewable Energy Sources: A Comprehensive Analysis

A Standard-Based Method to Simulate the Behavior of Thermal Solar Systems with a Stratified Storage Tank

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