Impact of dynamic thermal conductivity change of EPS insulation on temperature variation through a wall assembly

The purpose of this paper is to investigate the potential for calculation methods to determine the thermal resistance of a wall system containing vacuum insulation panels (VIPs) that has been experimentally characterised using a guarded hot box (GHB) apparatus. The VIPs used in the wall assembly have not been characterised separately to the wall assembly, and therefore exact knowledge of the thermal performance of the VIP including edge effect is not known. The calculations and simulations are completed using methods found in literature as well as manufacturer published values for the VIPs to determine the potential for calculation and simulation methods to predict the thermal resistance of the wall assembly without the exact characterisation of the VIP edge effect. The results demonstrate that disregarding the effect of VIP thermal bridges results in overestimating the thermal resistance of the wall assembly in all calculation and simulation methods, ranging from overestimates of 21% to 58%. Accounting for the VIP thermal bridges using the manufacturer advertised effective thermal conductivity of the VIPs resulted in three methods predicting the thermal resistance of the wall assembly within the uncertainty of the GHB results: the isothermal planes method, modified zone method and the 3D simulation. Of these methods only the 3D simulation can be considered a potential valid method for energy code compliance, as the isothermal planes method requires too drastic an assumption to be valid and the modified zone method requires extrapolating the zone factor beyond values which have been validated. The results of this work demonstrate that 3D simulations do show potential for use in lieu of guarded hot box testing for predicting the thermal resistance of wall assemblies containing both VIPs and steel studs. However, knowledge of the VIP effective thermal conductivity is imperative to achieve reasonable results.

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Field Test and Numerical Simulation on the Long-Term Thermal Response of PHC Energy Pile in Layered Foundation

Sensors ◽

10.3390/s21113873 ◽

2021 ◽

Vol 21 (11) ◽

pp. 3873

Author(s):

Guozhu Zhang ◽

Ziming Cao ◽

Yiping Liu ◽

Jiawei Chen

Keyword(s):

Thermal Conductivity ◽

Heat Exchange ◽

Temperature Variation ◽

Thermal Response ◽

Ground Temperature ◽

Short Term ◽

Energy Pile ◽

Backfill Soil ◽

Short And Long Term

Investigation on the long-term thermal response of precast high-strength concrete (PHC) energy pile is relatively rare. This paper combines field experiments and numerical simulations to investigate the long-term thermal properties of a PHC energy pile in a layered foundation. The major findings obtained from the experimental and numerical studies are as follows: First, the thermophysical ground properties gradually produce an influence on the long-term temperature variation. For the soil layers with relatively higher thermal conductivity, the ground temperature near to the energy pile presents a slowly increasing trend, and the ground temperature response at a longer distance from the center of the PHC pile appears to be delayed. Second, the short- and long-term thermal performance of the PHC energy pile can be enhanced by increasing the thermal conductivity of backfill soil. When the thermal conductivities of backfill soil in the PHC pile increase from 1 to 4 W/(m K), the heat exchange amounts of energy pile can be enhanced by approximately 30%, 79%, 105%, and 122% at 1 day and 20%, 47%, 59%, and 66% at 90 days compared with the backfill water used in the site. However, the influence of specific heat capacity of the backfill soil in the PHC pile on the short-term or long-term thermal response can be ignored. Furthermore, the variation of the initial ground temperature is also an important factor to affect the short-and-long-term heat transfer capacity and ground temperature variation. Finally, the thermal conductivity of the ground has a significant effect on the long-term thermal response compared with the short-term condition, and the heat exchange rates rise by about 5% and 9% at 1 day and 21% and 37% at 90 days as the thermal conductivities of the ground increase by 0.5 and 1 W/(m K), respectively.

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Temperature dependency of the long-term thermal conductivity of spray polyurethane foam

Journal of Building Physics ◽

10.1177/17442591211045415 ◽

2021 ◽

pp. 174425912110454

Author(s):

Neal Holcroft

Keyword(s):

Thermal Conductivity ◽

Polyurethane Foam ◽

Cellular Structure ◽

Gas Diffusion ◽

Temperature Dependent ◽

Blowing Agent ◽

Closed Cell ◽

Wall Assembly ◽

Cell Foam

The thermal properties of closed-cell foam insulation display a more complex behaviour than other construction materials due to the properties of the blowing agent captured in their cellular structure. Over time, blowing agent diffuses out from and air into the cellular structure resulting in an increase in thermal conductivity, a process that is temperature dependent. Some blowing agents also condense at temperatures within the in-service range of the insulation, resulting in non-linear temperature dependent relationships. Moreover, diffusion of moisture into the cellular structure increases thermal conductivity. Standards exist to quantify the effect of gas diffusion on thermal conductivity, however only at standard laboratory conditions. In this paper a new test procedure is described that includes calculation methods to determine Temperature Dependent Long-Term Thermal Conductivity (LTTC(T)) functions for closed-cell foam insulation using as a test material, a Medium-Density Spray Polyurethane Foam (MDSPF). Tests results are provided to show the validity of the method and to investigate the effects of both conditioning and mean test temperature on change in thermal conductivity. In addition, testing was conducted to produce a moisture dependent thermal conductivity function. The resulting functions were used in hygrothermal simulations to assess the effect of foam aging, in-service temperature and moisture content on the performance of a typical wall assembly incorporating MDSPF located in four Canadian climate zones. Results show that after 1 year, mean thermal conductivity increased 15%–16% and after 5 years 23%–24%, depending on climate zone. Furthermore, the use of the LTTC(T) function to calculate the wall assembly U-value improved accuracy between 3% and 5%.

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The Impact of Variable Thermal Conductivity of Insulation Materials on the Building Energy Performance in Hot Climate

E3S Web of Conferences ◽

10.1051/e3sconf/201910302001 ◽

2019 ◽

Vol 103 ◽

pp. 02001 ◽

Cited By ~ 3

Author(s):

Maatouk Khoukhi ◽

Ahmed Hassan ◽

Shaimaa Abdelbaqi

Keyword(s):

Thermal Conductivity ◽

Energy Performance ◽

Variable Thermal Conductivity ◽

Transfer Model ◽

Ambient Conditions ◽

K Value ◽

Hot Climate ◽

Building Wall ◽

Wall Assembly ◽

The Impact

This paper illustrates the impact of embedding an insulation layer of variable thermal conductivity in a typical building wall on the cooling effect and energy performance. The evaluation was performed by applying a conjugate heat transfer model, which was tested in extremely hot conditions of Al Ain (UAE). The thermal performance of a building incorporating insulation layers of variable thermal conductivity (k-value) was compared to a non-variable thermal conductivity system by quantifying the additional heat transferred due to the k-relationship with time. The results show that, when the k-value is a function of operating temperature, its effects on the temperature profile through the wall assembly during daytime is significant compared with that obtained when a constant k-value for the polystyrene (EPS) insulation is adopted. A similar trend in the evolution of temperatures during the day and across the wall section was observed when EPS material with different moisture content was evaluated. For the polyurethane insulation, the inner surface temperature reached 44 °C when constant k-value was adopted, increasing to 48.5 °C when the k-value was allowed to vary under the same ambient conditions.

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High Contrast Thermal Conductivity Change in Ni–Mn–In Heusler Alloys near Room Temperature

Advanced Engineering Materials ◽

10.1002/adem.201801342 ◽

2019 ◽

Vol 21 (5) ◽

pp. 1801342 ◽

Cited By ~ 1

Author(s):

Qiye Zheng ◽

Gaohua Zhu ◽

Zhu Diao ◽

Debasish Banerjee ◽

David G. Cahill

Keyword(s):

Thermal Conductivity ◽

Room Temperature ◽

Heusler Alloys ◽

High Contrast ◽

Conductivity Change

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Stretching-Induced Thermal Conductivity Change in Shape-Memory Polymer Composites

Journal of Heat Transfer ◽

10.1115/1.4046970 ◽

2020 ◽

Author(s):

Stephen Hostler ◽

Mohnish Peswani ◽

Han Yang ◽

Harrison Paul ◽

Stuart J. Rowan ◽

...

Keyword(s):

Thermal Conductivity ◽

Shape Memory ◽

Thermal Management ◽

Energy Savings ◽

Thermal State ◽

Shape Memory Polymer ◽

Applied Strain ◽

Proof Of Concept ◽

Conductivity Change ◽

The Matrix

Abstract Active thermal materials like thermal diodes, regulators, and switches have the potential to revolutionize thermal management, creating an opportunity for significant energy savings. We present results on a thermal switching composite that changes its thermal conductivity based on applied strain. The composite is constructed of highly-crystalline, high aspect ratio cellulose nanocrystal (CNC) nanorods embedded in a shape-memory polymer matrix. The properties of the matrix allow for changes to the thermal state to be indefinitely retained and also for the state to be reversed. A switching ratio of two is achieved for this proof-of-concept composite. By comparing the measured results to a Maxwell mixing model, the primary drivers of the thermal conductivity change are traced to changes in crystallinity of the matrix and CNC alignment.

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Thermal energy storage in embankments: Investigation of the thermal properties of an unsaturated compacted soil

E3S Web of Conferences ◽

10.1051/e3sconf/202020507011 ◽

2020 ◽

Vol 205 ◽

pp. 07011

Author(s):

Mojdeh Lahoori ◽

Sandrine Rosin-Paumier ◽

Yves Jannot ◽

Ahmed Boukelia ◽

Farimah Masrouri

Keyword(s):

Thermal Conductivity ◽

Thermal Properties ◽

Energy Storage ◽

Temperature Variation ◽

Thermal Energy ◽

Thermal Energy Storage ◽

Transient State ◽

Temperature Sensors ◽

Compacted Soils ◽

Compacted Soil

Thermal energy storage in compacted soils can be considered as a new economically efficient and environmentally friendly technology in geotechnical engineering. Compacted soils are usually unsaturated; therefore, reliable estimates and measurements of their thermal properties are important in the efficiency analysis of these structures. In this study, a method is used to estimate the thermal properties of an unsaturated compacted soil. Several temperature sensors were placed in a thermo-regulated metric scale container to monitor the imposed temperature variation in the range of the 20 to 50 °C. This imposed temperature variation reproduced the temperature variation in the thermal energy storages. An inverse analytical model based on a one-dimensional radial heat conduction equation is used to estimate the thermal diffusivity using the temperature variation between two temperature sensors. The volumetric heat capacity was measured using a calorimeter in the laboratory, enabling the estimation of the thermal conductivity of the compacted soil. Then, this estimated thermal conductivity was compared with the thermal conductivity values measured with two other methods (steady-state and transient-state method). The difference between them are discussed in terms of the sample heterogeneity, sample size, and measurement method.

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The thermal conductivities of some dielectric solids at low temperatures (Experimental)

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1951.0146 ◽

1951 ◽

Vol 208 (1092) ◽

pp. 90-108 ◽

Cited By ~ 116

Keyword(s):

Thermal Conductivity ◽

Thermal Resistance ◽

Specific Heat ◽

Temperature Variation ◽

Temperature Region ◽

Low Temperatures ◽

Quartz Crystal ◽

Corundum Crystal ◽

Before And After ◽

Dielectric Solids

An apparatus is described in which the thermal conductivity of solids can be determined at any temperature between 2 and 90°K. Several glasses and dielectric crystals have been measured. It had previously been found that at high temperatures the conductivity of glasses is proportional to the specific heat, but at low temperatures it falls off more slowly than the specific heat. The present experiments show that there is a temperature region in which the conductivity is nearly independent of temperature. A similar variation of conductivity is found for the thermo-plastic Perspex. The effect of lattice defects in crystals was studied by measuring the thermal conductivity of a quartz crystal before and after successive periods of neutron irradiation. After prolonged irradiation the conductivity approached, in both magnitude and temperature variation, that of quartz glass. Subsequent heating produced a substantial recovery in the conductivity. The results on both glasses and on crystals can be explained by the theory developed by Klemens (1951). Further measurements made on a corundum crystal confirm the importance of the ‘Umklapp’ processes, postulated by Peierls, in causing thermal resistance.

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Influence of Thermal Conductivity of Lubricant on the THD Characteristics of a Plain Journal Bearing

13th Biennial Conference on Mechanical Vibration and Noise: Rotating Machinery and Vehicle Dynamics ◽

10.1115/detc1991-0242 ◽

1991 ◽

Author(s):

C. Rajalingham ◽

B. S. Prabhu ◽

R. B. Bhat ◽

G. D. Xistris

Keyword(s):

Heat Transfer ◽

Thermal Conductivity ◽

Temperature Variation ◽

Heat Generation ◽

Journal Bearing ◽

Lubricant Film ◽

Fluid Film ◽

Adiabatic Conditions ◽

Viscous Heat ◽

Hydrodynamic Journal Bearing

Abstract The viscous heat generation in the lubricant film of a hydrodynamic journal bearing causes a rise in temperature of the fluid film. Considering the influence of the temperature variation along and across the film, the performance of a journal bearing is investigated under adiabatic conditions for different values of thermal conductivity of the lubricant. In this analysis, the temperature of the journal surface has been chosen to ensure that there is no net heat transfer from the lubricant The results show that the variation of temperature across the film affects bearing performance significantly and that an increase in lubricant thermal conductivity enhances bearing performance.

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