Investigations on thermal and optical performances of a glazing roof with PCM layer

Liu, Changyu; Wu, Yifan; Li, Dong; Ma, Tengfei; Liu, Xiaoyan

doi:10.1002/er.3775

Cited by 7 publications

(8 citation statements)

References 38 publications

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“…EnergyPlus uses an integrated, synchronized simulation approach, and the heat transfer in the wall is calculated using the conduction transfer functions (CTF). The energy load is calculated by heat balance, which contains the balance of the building's surface and the transient heat transfer through the building …”

Section: Resultsmentioning

confidence: 99%

“…The energy load is calculated by heat balance, which contains the balance of the building's surface and the transient heat transfer through the building. [35][36][37][38][39] As shown in Figure 10, a cube house model with a side length of 2.6 m was constructed with a window. The properties of two building envelope materials are shown in Table 6, and the weather data used for the simulation are the meteorological data of Guangzhou and Harbin, China, respectively ( Figure 11).…”

Section: Energy Assessment By Numerical Calculation Methodsmentioning

confidence: 99%

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Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building

Liu

Qiu

et al. 2019

Int J Energy Res

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Summary In this work, a novel Na2SO4·10H2O/fly ash shape‐stabilized phase change material mortar (PCM mortar) was prepared for building energy efficiency, in the context of energy conservation and environmental protection. The working, mechanical, and thermal properties of this proposed PCM mortar were investigated. The experiment results showed that the incorporation of PCMs greatly increased the thermal inertia of the mortar, while corresponding compressive strength was little affected. Specifically, when the blending amount of PCMs reached 15%, the thermal storage capacity of mortar sample (PCM‐15) was 6.18 × 104 kJ/m3, which is 2.4 times of that for mortar sample without PCM (OPC) evaluated by theoretical calculations, while the corresponding compressive strength of mortar sample (PCM‐15) still remained above 31 MPa. Furthermore, the effects of PCM mortar on thermal comfort and energy use of buildings were studied by using experiment and simulation methods, respectively. The control experiments showed that PCM mortar can effectively alleviate the influence of outdoor temperature on indoor temperature compared with OPC. Temperature difference between PCM‐15 and OPC board can reach 4.6°C (inner surface) and 8.6°C (outer surface), respectively. Meanwhile, temperature difference of internal space reached 1.2°C. The simulation results showed that the energy consumption per unit building area was reduced by 4.4 and 18.7 kg/m2 in Guangzhou and Harbin, respectively, with PCM mortar as the envelope structure. Hence, the proposed PCM mortar showed significant thermal and mechanical properties and had broad application prospects in regulating indoor temperature and constructing energy‐efficient buildings.

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Section: Resultsmentioning

confidence: 99%

Section: Energy Assessment By Numerical Calculation Methodsmentioning

confidence: 99%

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building

Liu

Qiu

et al. 2019

Int J Energy Res

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“…Although the measures to increase the thermal resistance of the envelop such as thermal insulation curtain can improve the energy saving rate to some extent, there are still limitations. The phase change materials (PCM) is a kind of material that can absorb or release heat in the process of its physical state change, and can also make use of the heat in this part, so as to carry out heat storage and indoor temperature regulation [7][8][9][10][11][12]. The application of PCM and other heat storage materials in the heat storage of the envelope can effectively maintain the thermal stability of the building and reduce the cost of building materials to a certain extent.…”

Section: Introductionmentioning

confidence: 99%

Analysis of thermal energy storage system for energy saving reconstruction of building in region with heating provision and high sunshine

Wang

2020

THERM SCI

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This research aims to analyze the effect of phase change energy storage wall on the internal thermal environment in high-sunshine passive solar residential buildings. The residential buildings in Lhasa are taken as research objects, and the differences in indoor and outdoor thermal environments of the residential buildings in winter are first evaluated. Then, the energy storage wall model based on phase change material is constructed, the meteorological data of the winter solstice day is used to simulate, and the changes of the thermal environment in the room are detected. The results showed that the average solar radiation intensity of the dwellings in Lhasa is 441.8 W/m 2 , and the average scattering intensity is 156.3 W/m 2. The average humidity and temperature of outdoor air are 24.4% and 1.54 °C, respectively. The temperature difference of the indoor south and north bedrooms is 3.3 °C, the internal temperatures of the indoor south and north walls are 13.4 °C and 7.9 °C, respectively, and the temperature difference is 5.5 °C. After the adoption of phase change energy storage materials, the indoor temperatures of the south and north walls on the winter solstice day are 16.75 °C and 16.52 °C, respectively, with a temperature difference of 0.23 °C. The inner surface temperatures of the south wall and the north wall increase by 25.0% and 109.1%, respectively, after adopting the phase change energy storage wall, indicating that applying the phase change energy storage wall to the passive solar residential buildings in Lhasa can effectively improve the indoor thermal environment.

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“…The positive impact of PCMs on the building annual cooling and heating loads in various climate zones is a common conclusion. More specifically, PCM can be integrated into different parts of the building, either in transparent or in translucent elements, to reduce its cooling and heating loads while its successful incorporation depends on a number of factors: the local climatic conditions, the building design and orientation, the equipment selection, the type and quantity of PCM used, the encapsulation method, the phase change temperature and the way the PCM is charged/discharged, the location of PCMs in the building structures, not to mention the utility rate policy, the occupancy schedule, and the control system in the building . Over the past few years, several reviews have been written on PCMs and their use in buildings, which is an indication of the increasing interest in PCMs worldwide .…”

Section: Introductionmentioning

confidence: 99%

“…More specifically, PCM can be integrated into different parts of the building, either in transparent or in translucent elements, to reduce its cooling and heating loads while its successful incorporation depends on a number of factors: the local climatic conditions, the building design and orientation, the equipment selection, the type and quantity of PCM used, the encapsulation method, the phase change temperature and the way the PCM is charged/ discharged, the location of PCMs in the building structures, not to mention the utility rate policy, the occupancy schedule, and the control system in the building. [16][17][18] Over the past few years, several reviews have been written on PCMs and their use in buildings, which is an indication of the increasing interest in PCMs worldwide. 11,12,15,[19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34] However, there are still some difficulties regarding the effective, reliable, and practical application of this technology given that most of the existing studies related to PCMs are based on numerical simulations, prototype experiments, or both, while applications in real buildings, although increasing, are still considered relatively inadequate to draw definitive conclusions or guidelines.…”

Section: Introductionmentioning

confidence: 99%

Life cycle analysis (LCA) and life cycle cost analysis (LCCA) of phase change materials (PCM) for thermal applications: A review

et al. 2017

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Summary Thermal storage systems development is under significant concern focusing mainly to the thermal energy storage use for thermal applications. On the other hand, the investigation of phase change materials (PCMs) in the building sector was tested consisting a very promising field of research and development. A number of substances have been tested as potential PCMs; however, only few of them have been further developed for commercial purposes. This is attributed to a number of thermophysical barriers, which make the applications of PCMs in buildings difficult. Several studies have examined the potential of PCM use, either incorporated into building envelopes or in heating and cooling applications. Regarding building envelope applications, PCMs are used to mainly ensure indoor thermal comfort and contribute to energy performance. The positive impact of PCMs on the building's annual cooling and heating loads in various climate zones is a common conclusion. Concerning heating and cooling applications, the main idea has been to substitute the storage medium with PCMs, which have higher storage capacity. Hence, the use of PCMs can be considered as scientifically mature, although there are still technical, environmental, and economic barriers. The present study is the state of the art of the existing research of PCM for thermal applications taking into consideration environmental (based mainly on life cycle analysis methodology) and economic performance (accounting to life cycle cost analysis methodology) criteria, while excluding solar power generation applications.

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Investigations on thermal and optical performances of a glazing roof with PCM layer

Cited by 7 publications

References 38 publications

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building

Analysis of thermal energy storage system for energy saving reconstruction of building in region with heating provision and high sunshine

Life cycle analysis (LCA) and life cycle cost analysis (LCCA) of phase change materials (PCM) for thermal applications: A review

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Investigations on thermal and optical performances of a glazing roof with PCM layer

Cited by 7 publications

References 38 publications

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na 2 SO 4 ·10H 2 O and fly ash for energy‐efficient building

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na 2 SO 4 ·10H 2 O and fly ash for energy‐efficient building

Analysis of thermal energy storage system for energy saving reconstruction of building in region with heating provision and high sunshine

Life cycle analysis (LCA) and life cycle cost analysis (LCCA) of phase change materials (PCM) for thermal applications: A review

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Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building

Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na ₂ SO ₄ ·10H ₂ O and fly ash for energy‐efficient building