Thermal Inertia Characterization of Multilayer Lightweight Walls: Numerical Analysis and Experimental Validation

Díaz, J.; Rabanal, Felipe Pedro Álvarez; Alonso-Martínez, Mar; Martínez-Martínez, Juan Enrique

doi:10.3390/app11115008

Cited by 7 publications

(5 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This effect could be explained by thermal inertia, meaning the variability in the capacity to reach a balance in core temperature when they are exposed to environmental conditions [69]. Although the meaning of thermal inertia is often applied to a physical object [70], the capacity to reach said balance might be affected by the disposition of blood capillaries in the different anatomical regions that can be considered thermal windows, as shown in Figures 4 and 5. Although the previous examples used anesthetics to understand the vasomotor response, this event could help us to comprehend how the change in diameter of the capillary influences the temperature of peripheral regions.…”

Section: Vasomotor Responsementioning

confidence: 99%

Hypothalamic Neuromodulation of Hypothermia in Domestic Animals

Mota-Rojas,

Ghezzi,

Hernández-Ávalos

et al. 2024

Animals

View full text Add to dashboard Cite

When an organism detects decreases in their core body temperature, the hypothalamus, the main thermoregulatory center, triggers compensatory responses. These responses include vasomotor changes to prevent heat loss and physiological mechanisms (e.g., shivering and non-shivering thermogenesis) for heat production. Both types of changes require the participation of peripheral thermoreceptors, afferent signaling to the spinal cord and hypothalamus, and efferent pathways to motor and/or sympathetic neurons. The present review aims to analyze the scientific evidence of the hypothalamic control of hypothermia and the central and peripheral changes that are triggered in domestic animals.

show abstract

Section: Vasomotor Responsementioning

confidence: 99%

Hypothalamic Neuromodulation of Hypothermia in Domestic Animals

Mota-Rojas,

Ghezzi,

Hernández-Ávalos

et al. 2024

Animals

View full text Add to dashboard Cite

show abstract

“…A convection model was implemented over the top surface of the model, assuming an ambient temperature of 20 • C and a convective surface coefficient of 5.0 W/K m 2 , following the guidelines established in Annex C of the UNE-EN ISO 6946:2021 [56] standard. The experimental temperature measurements registered at the top and bottom points of the swale laboratory models were used as input data for the previously validated FEM model [57], which yielded errors below 2%.…”

Section: Steady-state Thermal Modelmentioning

confidence: 99%

Experimental and Numerical Study of the Thermal Properties of Dry Green Swales to Be Used as Part of Geothermal Energy Systems

Rey-Mahía,

Álvarez-Rabanal,

Sañudo-Fontaneda

2023

Applied Sciences

Self Cite

View full text Add to dashboard Cite

Low-enthalpy geothermal systems are a promising source for renewable and clean energy for heating, cooling, and air conditioning residential buildings, contributing to the reduction in greenhouse gas emissions in line with the United Nations’ Sustainable Development Goals. Previous research emerged around the geothermal utilization of Sustainable Drainage Systems (SuDS) as multifunctional surfaces for stormwater control and energy saving, developing the water–energy nexus. However, these studies did not comprehensively considered the energy aspects for SuDS design, using non-standardized tests to measure the main thermal parameters. This research aims to address this gap by proposing a novel hybrid engineering procedure to study the thermal properties of SuDS layers and materials through experimental tests combined with steady-state and transient numerical simulations, using green swales operating under dry and wet conditions as a first case study for SuDS techniques. Novel materials incorporated into dry swales (expanded clay and construction and demolition waste) were tested. The results validated this new methodology, reporting an increase of 87% under dry conditions, and 51% under wet scenarios in the thermal insulation performance in comparison to standard materials. A better thermal performance of the systems can be achieved by approaching SuDS design from a holistic viewpoint that integrates energy aspects.

show abstract

“…The temperature values obtained experimentally at the top and bottom parts of the roof were used as input data for the FEM model. This model, used in previous works [34], was used and it provides errors below a threshold of 2%.…”

Section: Numerical Modelsmentioning

confidence: 99%

An Experimental and Numerical Approach to Multifunctional Urban Surfaces through Blue Roofs

et al. 2022

Self Cite

View full text Add to dashboard Cite

Uncontrolled urban growth causes a number of problems associated with land use, stormwater management and energy generation. Sustainable Urban Drainage Systems (SUDS) are positioned as an alternative to traditional constructive solutions, contributing towards the generation of multifunctional urban spaces for efficient stormwater management and energy consumption reduction. Nevertheless, this combined goal calls for a deeper understanding of the heat transfer processes that govern the temperature performance in SUDS in order to be further validated as infrastructure to house renewable energy elements. This study intends to determine the thermal properties of two types of blue roofs under extreme conditions of performance (wet and dry), depicting the operation features of their layers and comparing their performances based on the materials used. With this aim, a hybrid experimental methodology, combining laboratory and numerical modelling, was designed using standardized equipment (ISO 8990:1994 and ASTM C1363-05), improving previous methods proposed in the study of the thermal properties of SUDS. The section with expanded clay improved the hydraulic capacity by 4.8%. The section without expanded clay increased its thermal transmittance value by 64.9% under wet conditions. It was also found that the presence of water increased the equivalent thermal conductivity in both sections by 60%.

show abstract

Thermal Inertia Characterization of Multilayer Lightweight Walls: Numerical Analysis and Experimental Validation

Cited by 7 publications

References 24 publications

Hypothalamic Neuromodulation of Hypothermia in Domestic Animals

Hypothalamic Neuromodulation of Hypothermia in Domestic Animals

Experimental and Numerical Study of the Thermal Properties of Dry Green Swales to Be Used as Part of Geothermal Energy Systems

An Experimental and Numerical Approach to Multifunctional Urban Surfaces through Blue Roofs

Contact Info

Product

Resources

About