Assessment of Heat Recovery and Recovery Efficiency of a Seasonal Thermal Energy Storage System in a Moist Porous Medium

Dada, M.; Benchatti, Ahmed

doi:10.18280/ijht.340421

Cited by 9 publications

(3 citation statements)

References 3 publications

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“…(5) Entransy of supply water The Entransy of the supply water is defined by Equation (18). Space heating can be expressed using Equation (19).…”

Section: Performance Evaluation Indexesmentioning

confidence: 99%

“…The results indicated a thermal recovery ratio of less than 67% and different temperature distributions under the three modes. Dada [19] simulated a novel seasonal heat-storage system dedicated to storing heat in the ground during the hot period and then recovering it during the cold period. This approach led to a remarkable increase in temperature levels as well as heat-energy recovery efficiency, which increased from 41% to 71%.…”

Section: Introductionmentioning

confidence: 99%

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Study on the Performance of a Solar Heating System with Seasonal and Cascade Thermal-Energy Storage

Yue

Xu²,

Zhou³

et al. 2022

Energies

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Seasonal solar thermal-energy storage systems used for space heating applications is a promising technology to reduce greenhouse gas emissions. A novel solar heating system with seasonal and cascade thermal-energy storage based on zeolite water is proposed in this study. The system's efficiency is improved through cascade storage and the release of solar energy. The energy storage density is improved through the deep coupling of daily energy storage and cross-seasonal energy storage. A mathematical model of the system-performance analysis is established. The system performances in the non-heating and heating seasons and throughout the year are analyzed by considering the Chifeng City of China as an application case. The results indicate that the average collection efficiency of the proposed system is 2.88% higher in the non-heating season and 7.4% higher in the heating season than that of the reference system. Furthermore, the utilization efficiency of the proposed system is 37.16%, which is 3.26% higher than that of the reference system. Further, the proposed system has a supply heat of 2135 GJ in the heating season, which is 9.66% higher than the reference system. This study provides a solution for the highly efficient solar energy utilization for large-scale space-heating applications.

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“…(5) Entransy of supply water The Entransy of the supply water is defined by Equation (18). Space heating can be expressed using Equation (19).…”

Section: Performance Evaluation Indexesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study on the Performance of a Solar Heating System with Seasonal and Cascade Thermal-Energy Storage

Yue

Xu²,

Zhou³

et al. 2022

Energies

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“…Their study pointed out that the triple helix heat exchanger was better than the other configurations. Dada et al (2016) simulated several case studies with different types of hot fluid carrier, and indicated that the effect of pure water as circulating fluid was better than that of ethylene glycol and gasoline. Kong et al (2017) analyzed the thermal performance of a set of buried vertical U-tubes designed with different petals for ground-source heat pump and investigated different influential factors of thermal response.…”

Section: Introductionmentioning

confidence: 99%

Comparative study on the thermal performance and economic efﬁciency of vertical and horizontal ground heat exchangers

Cui

Jiao

2022

Adv. Geo-Energy Res.

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The ground-coupled heat pump is a shallow geothermal exploitation method taking soil as the thermal energy source. The ground heat exchanger is an important component of this system, which includes vertical or horizontal configurations. However, to the best of our knowledge, few studies exist involving the comparison of thermal performances and installation costs of two heat exchanger types considering the influence of ground climate, which makes the selection of heat exchanger configuration challenging for a specific field application. Hence, a 3-dimensional numerical model considering the variations of atmospheric conditions and soil water content is constructed in this paper. Based on this model, the thermal performances and economical efficiencies of vertical and horizontal ground heat exchangers are compared. The results indicate that the thermal performance difference between the two heat exchangers is greater in winter than in summer. The thermal performance is hardly influenced by the injection mass flow rate, while it is considerably affected by the length of heat exchanger. The thermal power rises linearly with the increase in heat exchanger length, and the increment of the vertical ground heat exchanger is higher. In addition, when the heat exchanger length is shorter than 40 m, the installation cost and thereby the total cost of the horizontal ground heat exchanger is considerably higher. With regard to both the thermal performance and economic efficiency, a vertical ground heat exchanger is only recommended when installing a single shallow ground heat exchanger.

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The effects of ground heat exchanger parameters changes on geothermal heat pump performance – A review

Noorollahi

Saeidi

Mohammadi

et al. 2018

Applied Thermal Engineering

129

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Assessment of Heat Recovery and Recovery Efficiency of a Seasonal Thermal Energy Storage System in a Moist Porous Medium

Cited by 9 publications

References 3 publications

Study on the Performance of a Solar Heating System with Seasonal and Cascade Thermal-Energy Storage

Study on the Performance of a Solar Heating System with Seasonal and Cascade Thermal-Energy Storage

Comparative study on the thermal performance and economic efﬁciency of vertical and horizontal ground heat exchangers

The effects of ground heat exchanger parameters changes on geothermal heat pump performance – A review

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