When the transition from winter to spring unfolds and the heating season draws to a close, the importance of warmth may ebb. However, scientists are quick to remind us that heat, rather than being seen as merely a seasonal necessity, is a significant energy resource that can be harnessed, stored, and utilized when needed most. A pivotal breakthrough comes from the researchers at the esteemed Kaunas University of Technology (KTU), who are revealing a transformative concept hidden within our very own soil: the potential for ground-based thermal energy storage.
Led by KTU professor Dr. Tadas Ždankus, a team of researchers is delving into the multifaceted capabilities of soil, exploring its role not only in construction but as an innovative medium for heat retention. Central to their investigation is a ground-based heat accumulator designed to capture excess thermal energy and store it beneath the surface, making it accessible during peak demand periods. “Our objective was to convert heat that would typically dissipate into the ground as waste into a valuable energy resource,” elaborates Dr. Ždankus, providing insight into the groundbreaking work being undertaken.
The research indicates that the underground holds vast potential for efficient heat storage. Initially, Professor Ždankus and his team explored the applicability of wind energy, primarily focused on how it could generate heat without the need for traditional electricity generation. By employing a hydraulic system, they discovered a fascinating phenomenon: hydraulic losses, often viewed as inefficiencies, can actually produce usable heat. “The hydraulic losses we were attempting to minimize ultimately emerged as significant heat generation,” states Dr. Ždankus, highlighting a key reevaluation of conventional assumptions.
Moreover, the challenge of heat loss during transmission to buildings intended for heating during colder months prompted the research question. The pressing inquiry sought to pinpoint not only methods of reducing ground heat loss but also strategies to effectively store and retain it for future utilization. “We wanted to address the core issue of heat retention alongside its generation,” adds Ždankus, emphasizing the dual focus of their studies.
To validate their conceptual framework, the researchers engaged in experimental trials that simulated the introduction of an artificial heat source within the upper layers of soil. They meticulously measured the dynamics of heat distribution, the velocity of its movement through the ground, and the duration of its persistence. One compelling test involved heating the soil to a point where moisture began to evaporate, leading to a critical phase change from liquid to vapor, which is an integral aspect of thermal energy storage.
“Phase change serves as an efficient medium for heat storage, allowing for a substantially greater amount of energy to be embedded within the soil,” notes a KTU professor. The movement of vapor through the ground not only enhances heat diffusion but also enables precise control over energy distribution. “Wherever vapor flow reaches, we observed a notable temperature increase, signifying that the energy is mobilizing effectively,” explains Professor Ždankus, underscoring the significant implications of their findings.
The potential applications for such a system are extensive, with possibilities for balancing district heating networks or providing relief during periods of electricity grid overload. “Additionally, the installation of thermal accumulators for individual use beneath residential structures, streets, or parking lots could become a practical reality,” he adds, urging further exploration of these innovative applications. The research underscores that the efficiency of underground heat storage may exceed previous expectations, paving the way for a sustainable energy future.
Expanding upon the confirmation of the feasibility of underground heat storage, the researchers have begun investigating practical implementations. Their early endeavors sought to understand whether the soil located under buildings could play a passive role in thermal retention, reiterating the natural downward flow of heat from structures into the earth. “Our laboratory work led us to the development of a prototype ground energy cell, coupled with a testing setup to analyze the patterns of heat propagation within various soil layers,” Dr. Ždankus explains.
The study also involved comprehensive assessments of how effectively the soil could store heat over time and the speed at which it returned to its baseline temperature. These pivotal findings are essential for gauging the long-term viability of subterranean heat storage systems. The research initiative also engaged KTU master’s students, allowing for a collaborative investigation that spanned an entire year. The extensive chronological data collection facilitated analysis of seasonal thermal behavior and enabled meaningful comparisons with meteorological data.
“Our year-long data collection revealed inherent seasonal trends in soil temperature, providing insightful perspectives on natural patterns,” notes Professor Ždankus, as he outlines the importance of this collaborative effort. Additionally, detailed numerical simulations were conducted to evaluate potential heat losses, establishing the effectiveness of heat storage beneath buildings. “We found that even a passive approach to utilizing isolated soil volumes beneath buildings can significantly curtail heat loss while bolstering overall energy efficiency. Reduced heat loss translates to decreased energy requirements for heating, which, in turn, correlates with lower carbon emissions when derived from fossil fuels or biomass,” elucidates Ždankus.
In light of their promising results, the researchers are diligently working on refining their prototypes and enhancing heat distribution control technologies. The collaborative approach undertaken by the researchers encompasses a diverse range of expertise, ranging from geotechnical engineering to energy systems optimization. “Our imminent objective is to integrate current methodologies, including boreholes and piles, along with various underground heat exchange technologies, into a cohesive framework capable of benefiting both industrial and residential sectors,” he concludes.
The groundbreaking research emerging from Kaunas University of Technology emphasizes the vast, untapped potential of underground heat storage systems. By reimagining the role of soil in energy efficiency and heat retention, the work not only signifies a shift in understanding but also heralds an avenue for innovative solutions to energy management challenges. The implications of this research are poised to extend far beyond academic curiosity, with tangible benefits that can contribute to a sustainable energy landscape for future generations.
Subject of Research: Underground Heat Storage
Article Title: Research on Increasing the Building’s Energy Efficiency by Using the Ground Beneath It for Thermo-Accumulation
News Publication Date: 2-Jan-2025
Web References: Sustainability
References: DOI
Image Credits: KTU
Keywords
Underground energy storage, thermal energy, heat retention, soil science, energy efficiency, sustainable energy solutions, phase change, geothermal heating.
Tags: energy resource managementenvironmental impact of heat storageground-based heat accumulatorsinnovative energy storage methodsKaunas University of Technology researchKTU research innovationsRenewable Energy Technologiesseasonal heat retentionsoil as a heat mediumsoil thermal energy storagesustainable energy solutionsthermal energy utilization