THERMAL SCIENCE

International Scientific Journal

Authors of this Paper

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Aixue Xu

,

Huijuan Qi

,

Hongnian Wen

THERMAL ENERGY STORAGE TECHNOLOGY AND ITS APPLICATION IN POWER DATA REMOTE TRANSMISSION

ABSTRACT
In order to meet the current situation of the strong growth of energy demand, the authors put forward the research of thermal energy storage technology and its application in power data remote transmission. The main content of the technology is based on heat energy storage technology, discuss the advantages of heat energy storage technology, and study the stability analysis in the remote transmission of power data, finally, the stability performance of heat energy storage technology in power data remote transmission is obtained through experiments. The experimental results show that the energy storage is added at bus 6 of the power supply end, and the transmission distance between the energy storage power station and bus 6 is changed and the energy storage output is kept at 100 MW, the power of the connecting line is 400 MW. With the increase of the transmission distance, the variation trend of the interregion oscillation mode and the oscillation mode in Region 1 and Region 2 is that the oscillation frequency increases, the characteristic root moves to the left and the damping ratio increases, but the change is small. In conclusion it proves that heat energy storage technology has outstanding advantages, it has a broad development prospect and an important role in power data remote transmission.
KEYWORDS
heat energy, storage technology, power data, remote transmission
PAPER SUBMITTED: 2022-08-10
PAPER REVISED: 2022-10-08
PAPER ACCEPTED: 2022-10-26
PUBLISHED ONLINE: 2023-03-25
DOI REFERENCE: https://doi.org/10.2298/TSCI2302175X
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Issue 2, PAGES [1175 - 1181]
REFERENCES
  1. Li, Z., et al., Optimal Stochastic Deployment of Heterogeneous Energy Storage in a Residential Multienergy Microgrid with Demand-Side Management, IEEE, 6 (2021), 1, pp. 11-15
  2. Mehari, A., et al., Multi-Functional Three-Phase Sorption Solar Thermal Energy Storage Cycles for Cooling, Heating, and Heat Transformer, Applied Thermal Tngineering: Design,Pprocesses, Equipment, Economics, 3 (2021), 189
  3. Rivera, L. M., Flores, H. V., Techno-Economic Analysis of a Solar Tower CSP Plant with Thermal Energy Storage in Southern Honduras, IOP Conference Series: Earth and Environmental Science, 813 (2021), 1, 012002
  4. Re, A., et al., Experimental Investigations on Thermophysical Properties of Nanoenhanced Phase Change Materials for Thermal Energy Storage ApplicationsL, Alexandria Engineering Journal, 61 (2022), 9, pp. 7037-7044
  5. Misha, Krassovski, J. B., et al., Hybrid Energy Module for Remote Environmental Observations, Experiments, and Communications, Advances in Polar Science, 31 (2020), 80, pp. 7-17
  6. El-Arsh, H. Y., et al., Performance Comparison among Popular Implementations of h.264 Encoders, IOP Conference Series: Materials Science and Engineering, 1172 (2021), 1, 012036
  7. Du, X., et al., Activity and Water Footprint of Unconventional Energy Production under Hydroclimate Variation in Colorado, ACS ESAndT Water, 1 (2021), 2, pp. 281-290
  8. Kalunta, F., Ngwu, O., Enhancement of Transmission Efficiency and Voltage Profile in the Bauchi Axis of Nigerian Power Grid Using a VSC-HVDC System, American Journal of Electrical and Electronic Engineering, 9 (2021), 1, pp. 12-20
  9. Solar, L. C., et al., A New Approach to Three-Phase Asynchronous Motor Model for Electric Power System Analysis, 25 (2021), 3, 4
  10. Chen, Z., et al., A New Multilevel Compensation System for Neutral Active Grounding in Distribution Grid, IOP Conference Series: Earth and Environmental Science, 772 (2021), 1, 012017
  11. Khan, A. I., et al., Electro-Thermal Confinement Enables Improved Superlattice Phase Change Memory, IEEE Electron Device Letters, 6 (2022), 2, 43
  12. Gautam, A., Saini, R. P., A Review on Sensible Heat Based Packed Bed Solar Thermal Energy Storage System for Low Temperature Applications, TERI Information Digest on Energy and Environment: TIDEE, 9 (2021), 1, 20
  13. Bruch, A., et al., Physical Insight and Modelling of a Coupled Sensible and Moisture Storage for Dry Cooler Enhancement, Applied Thermal Engineering: Design, Processes, Equipment, Economics, 6 (2022), 207
  14. Singh, M., et al., Computational Prediction of Significant Efficiency Gain through Multi-Tank Modular Heat Storage for Solar Thermal Systems with Variable-Temperature Input Profile, Thermal Science and Engineering Progress, 12 (2020), 18
  15. Ahamed, S. C., A Review on the Use of Coconut Oil as an Organic Phase Change Material with Its Melting Process, Heat Transfer, and Energy Storage Characteristics, Journal of Thermal Analysis and Calorimetry, 56 (2022), 7, 147
  16. Malik, M. S., et al., Analysis of Energy Management and Battery Sizing in an off‐Grid Hybrid Solar Thermoelectric Generation System, Energy Technology: Generation, Conversion, Storage, Distribution, 97 (2022), 3, 10
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Thermal energy storage technology and its application in power data remote transmission

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence