11 results on '"latent heat storage"'
Search Results
2. Numerical thermal performance assessment of phase change process in a PCM/foam-fins enclosure under various thermal conditions.
- Author
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Rahmanian, Saeed, Rahmanian-Koushkaki, Hossein, Moein-Jahromi, Mahbod, and Setareh, Milad
- Subjects
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PHASE change materials , *FINS (Engineering) , *HEAT storage , *POROUS materials , *NATURAL heat convection , *LATENT heat , *HEAT transfer - Abstract
The low ability of phase change material (PCM) to transfer thermal energy has created a serious challenge for the development of latent heat storage (LHTES) units. Embedding foam with high thermal conductivity material like copper has attracted significant attention. Besides, high porosity, lightweight, and easy usage are other important benefits of copper. However, its higher cost and decreasing effective volume of PCM led to the creation of amendments in the foam design. Employment of the foam in the form of fin or foam fin has emerged as an alternative method to benefit from the advantages of porous material and overcome its defects. In this study, various LHTES units with different numbers of foam fins have been simulated numerically and compared with pure PCM and fully foam PCM enclosures. Two practical boundary conditions including constant temperature and constant heat flux were examined for the designed systems. The obtained results demonstrated that foam fins have a remarkable effect on the thermal performance enhancement of LHTES under constant temperature boundary condition. For LHTES with six foam fins, 42% and 30% reductions in melting time were achieved for both types of boundary conditions including constant temperature and heat flux, respectively. At the beginning of charging process, a significant enhancement of input heat rate was proved for LHTES with 6 foam fins and fully foam up to 112% and 155%, respectively. In addition, the foam fins method provided some free volume of PCM to permit the falling out of natural convection of molten PCM. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
3. On the design of a solar heat storage tank at 120°C.
- Author
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Christodoulaki, R., Akmandor, I. S., Bayer, O., Desideri, U., Ferrari, L., Frate, G. F., and Drosou, V.
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SOLAR heating , *HEAT pumps , *STORAGE tanks , *PHASE change materials , *HEAT storage , *LATENT heat , *RANKINE cycle , *MELTING points - Abstract
This work presents the materials selection process, the design and the dimensioning process of a latent heat storage tank that works between a high temperature heat pump and an Organic Rankine Cycle unit. The selected heat storage material is the S117 Phase Change Material that has a melting point at 117°C matches the operational temperature of the system at approximately 120°C. The tank configuration is selected for optimised heat transfer process, resulted from practical experience of the project partners and it is described in details in the document. The simulation results from the Computational Fluid Dynamic study of the tank are also presented here. This work should be useful for engineers designing compact heat storage tanks for medium temperature applications. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
4. Recent review of using nanofluid based composite PCM for various evacuated tube solar collector types.
- Author
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Mahdi, Noora S., Eidan, Adel A., Abada, Hashim H., and Al-Fahham, Mohamed
- Subjects
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SOLAR collectors , *NANOFLUIDS , *ELECTRIC power , *HEAT pipes , *SOLAR thermal energy , *HEAT storage , *RENEWABLE energy sources , *LATENT heat - Abstract
Recently, solar thermal energy has been considered the main type of renewable energy used widely to provide heat energy and produce electrical power. Evacuated tube solar collectors (ETSCs) are used in various weather circumstances such as clear, cloudy, windy, hot, and cold weather, and their efficient system supplies latent heat storage fluid with higher temperature and lower heat energy loss compared to the flat-plate solar collectors (FPSCs). This review paper is considered an investigation on adding nanofluid particles to the evacuated tube solar collector-PCM, indicating future evacuated tube solar collector designs and predicting the suitable high- or low-temperature PCM for various types of applications. Also, three main types of ETSCs, heat pipe, Thermosyphon, and U-pipe, with their applications are reviewed, and the factors that influence the collector performance and efficiency are discussed. Moreover, the properties that affect the selection of the PCM and the usage of various types, sizes, and volumetric concentrations of nanofluid as a working fluid for each ETSC are investigated with their enhancements for each type. Lastly, this paper provides future ideas for using additive nanofluid materials as a working fluid to improve the performance and efficiency of ETSCs. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
5. Revolutionizing heat recovery in shell-and-tube latent heat storage systems: an arc-shaped fin approach.
- Author
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Boujelbene, Mohamed, Mahdi, Jasim M., Dulaimi, Anmar, Ramezanimouziraji, Hosseinali, Ibrahem, Raed Khalid, Homod, Raad Z., Yaïci, Wahiba, Talebizadehsardari, Pouyan, and Keshmiri, Amir
- Subjects
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HEAT storage , *HEAT recovery , *LATENT heat , *HEATING , *ENERGY conservation in buildings , *SOLAR thermal energy , *ENERGY storage , *SOLAR technology - Abstract
Strengthening the thermal response of Phase-Change Materials (PCMs) is an essential and active field of research with promising potential for advanced applications such as solar energy storage, building energy conservation, and thermal management in electronic devices. This article evaluates the efficacy of a new arc-shaped fin array in shell-and-tube heat storage systems to enhance the PCM response during the discharge mode. Different fin geometric parameters including the fin curvature angle, the fin spacing, and the nonuniform angle between fins in the top and bottom sections of the PCM domain were considered to identify the best-performing layout. The analysis shows that increasing the curvature of arc-shaped fins between 60° and 180° and increasing the fin spacing between 5 and 15 mm can significantly reduce solidifying time and improve heat recovery rates. Moreover, the arc-shaped fins are more efficient than conventional longitudinal (+-shaped) fins, which are commonly employed in thermal energy storage applications. Arc-shaped fins can also save discharge time by more than half and improve the rate of heat recovery by almost four times than that of+-shaped fins. The present findings suggest that arc-shaped fins represent a promising design for enhancing the heat-recovery aspects in PCM-based energy storage systems. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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6. Solidification time and solid fraction of vertical concentric shell and tube latent heat storage device : A dimensionless parametric study and correlations development.
- Author
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Raj, Lanka Sandeep, Sreenivasulu, Sane, and Prasad, Bandaru Durga
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HEAT storage devices , *LATENT heat , *PARAMETRIC devices , *HEAT storage , *SOLIDIFICATION - Abstract
Thermo-hydraulic behavior of a Phase Change Material (PCM) plays a crucial role in deciding the performance of Latent Heat Storage (LHS) devices. Discharge or Solidification is the prime portion that determines the performance of the LHS device. This work numerically models solidification in a vertical tube-in-tube LHS device. The phase change is accounted for using the fixed grid enthalpy porosity method. An independent numerical model built is validated with the experimental model. Dimensionless parameters, namely Rayleigh Number, Stefan number, Reynolds Number, and L/D ratio, vary in the range of 9.19x105 to 39.45x105, 0.2 to 0.5, 600 to 3000, and 1 to 15, respectively. Among all parameters, the Stefan Number has the greatest impact on the solid fraction and solidification time. For estimating the Solidification Time and Solid Fraction, correlations are proposed. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
7. Performance comparison of sensible and latent heat-based thermal storage system during discharging – an experimental study.
- Author
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Suresh, C. and Saini, R.P.
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HEAT storage , *ENERGY storage , *LATENT heat , *HEAT recovery , *ENERGY conservation , *SOLAR thermal energy - Abstract
Thermal energy storage system has significant influence on energy conservation. Based on the literature review, it is identified that very few studies have been reported on performance assessment of latent and sensible thermal energy storage systems. This study presents an experimental study on latent and sensible thermal energy storage systems to investigate their performance during discharging cycle. Results have shown that the latent heat storage system has improvement of about 104% in discharging time and 4.1 times more energy is recovered as compared to the sensible heat storage system. It is recommended on the basis of obtained results to operate the systems at lower mass flow rate during discharging. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
8. A comprehensive review on mobilized thermal energy storage.
- Author
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Anandan, Shanmuga Sundaram and Sundarababu, Jagannathan
- Abstract
Industrial applications consume about one–third of global demand and account for nearly fifty percent of unutilized waste heat. Industrial waste heat recovery is a suitable solution. The tapping of waste heat from industrial activities has become inevitable energy conservation technology to reduce energy consumption and minimize the usage of fossil fuels to reduce carbon dioxide emissions. The conventional waste heat recovery installed on-site to meet local energy demand is a well-established technology. However, the topological mismatch between energy recovery and its demand remains a hurdle, especially for off-site heat demand located far away from sources. The Mobilized Thermal Energy Storage (MTES) alligates this issue. The economic and environmental study of MTES revealed that the standard energy cost (€/MWh) is proportional to transport distance. The energy cost (€/MWh) ranges from 40 to 80 with latent heat storage capacities latent heat storage capacity between 1.4 and 2.5 MWh and transport distance of 2 to 50 Km between source and end-users. The use of MTES reduces carbon emission up to 90% in comparison with conventional heating. Therefore, the transportation of waste utilizing thermal energy storage has become a trusted area of research. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
9. Comparative analysis of solid and perforated fins for thermal enhancement of a latent heat storage unit positioned at various inclinations.
- Author
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Kalapala, Lokesh and Krishna Devanuri, Jaya
- Abstract
Augmentation of the charging/discharging rate of the latent heat storage unit (LHSU) is one of the challenges in the design and development of the energy storage unit. Natural convection plays a pivotal role in this aspect which gets influenced by the inclination at which LHSU is placed. Employing radial fins enhance the heat transfer rate but there is a possibility of suppressing the natural convection. Providing perforations on the fins could assist the melted PCM to flow freely upwards and hence can overcome the issue of attenuation of natural convection. However, the orientation of LHSU may alter the influence of perforations. Hence in the current study, a comparative analysis on the thermal performance of a LHSU with solid and perforated fins at different orientations is presented. Experiments are carried out for both melting and solidification processes. It is observed that irrespective of the type of fin, orientation has a significant effect on the melting process. Regardless to the type of fin, total melting time is found to be 48% lesser in the vertical configuration in comparison with horizontal configuration. The considered design of perforations is found to be more effective in a vertical configuration as they increased the energy storage rate in the initial stages of melting. At other orientations, perforations do not have an ample effect. Fin effectiveness is observed to be 5% more in the case of solid fins in comparison with perforated fins at all the orientations. For the solidification process, orientation and perforations have negligible effect as the discharging process is conduction dominant. Exergy efficiency is noticed to be higher for vertically oriented LHSU in both the types fins during the charging process. During solidification of PCM, exergy efficiency is noticed to be same at all the orientations irrespective of the type of fin. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
10. Preparation, characterization, and performance study of beeswax/expanded graphite composite as thermal storage material.
- Author
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Dinker, A., Agarwal, M., and Agarwal, G. D.
- Subjects
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GRAPHITE composites , *HEAT storage , *BEESWAX , *THERMAL conductivity , *MELTING points - Abstract
In this study, beeswax as a new energy storage material and its composite with expanded graphite were prepared and characterized for their surface and thermal properties. Surface characterization showed no chemical interaction between beeswax and expanded graphite. The thermal conductivity of the composite was improved with 117% enhancement. The thermal performance of beeswax and its composite as a heat storage material was studied in a rectangular shell-and-tube thermal storage unit. The melting point of the composite remained almost same as that of beeswax; however, the melting time was reduced considerably, from 540 to 360 min with inlet water at 80°C and a 2-lpm flow rate. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
11. Experimental Investigation of a Cascaded Latent Heat Storage System for Diesel Engine Waste Heat Recovery.
- Author
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Chinnapandian, M., Pandiyarajan, V., Prabhu, A., and Velraj, R.
- Subjects
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HEAT storage , *HEAT recovery , *INTERNAL combustion engines , *ENERGY conservation , *COMPUTER simulation , *DIESEL motors - Abstract
Thermal storage plays a vital role in improving the overall efficiency of a waste heat recovery system. A phase change storage system exhibits high energy storage density and isothermal behavior during the charging and discharging processes. In the present work, the cascading arrangement of the phase change storage system is studied to analyze the improvement in the efficiency of the storage system during the charging process, and to compared it with a single storage tank system. The performance parameters, such as the amount of heat recovered, the heat lost, charging rate, charging efficiency, and the percentage of energy saved, are investigated in detail. [ABSTRACT FROM PUBLISHER]
- Published
- 2015
- Full Text
- View/download PDF
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