Materials For Energy Conservation Research Articles

A Comprehensive Review and Recent Trends in Thermal Insulation Materials for Energy Conservation in Buildings

In recent years, energy conservation became a strategic goal to preserve the environment, foster sustainability, and preserve valuable natural resources. The building sector is considered one of the largest energy consumers globally. Therefore, insulation plays a vital role in mitigating the energy consumption of the building sector. This study provides an overview of various organic and inorganic insulation materials, recent trends in insulation systems, and their applications, advantages, and disadvantages, particularly those suitable for extreme climates. Moreover, natural and composite materials that can be used as a low-cost, thermally efficient, and sustainable option for thermal insulation are discussed along with their thermal properties-associated problems, and potential solutions that could be adopted to utilize natural and sustainable options. Finally, the paper highlights factors affecting thermal performance and essential considerations for choosing a particular insulation system for a particular region. It is concluded that the most commonly used insulation materials are found to have several associated problems and there is a strong need to utilize sustainable materials along with advanced materials such as aerogels to develop novel composite insulation materials to overcome these deficiencies.

Simultaneous Boosting Nitrogen Reduction Activity and Suppressing Hydrogen Evolution Reaction Activity of Transition Metal Oxide Based Electrocatalyst

Ammonia (NH3) is widely served as fertilizer, safer chemical hydrogen storage, and energy conservation materials with an annual production around 200 million tons per year. Currently, NH3 is mainly synthesized via the Haber-Bosch process, which is an extremely energy- and capital-intensive (high temperature 400–500 °C and high pressure 100–350 atm) process, consuming over 1% of the global annual energy output, emitting massive amount of greenhouse gases (~420 Mt CO2 annually), and causing serious concerns with climate change. Electrochemical nitrogen reduction reaction (eNRR) allows NH3 production from nitrogen (N2) and water (H2O) under ambient conditions. Especially if driven by renewable energies, NRR represents a potentially clean and sustainable strategy for replacing the traditional Haber-Bosch process and alleviating climate change effect. One of the most critical fundamental challenges in production of ammonia via electrochemical nitrogen reduction reaction (eNNR) is developing catalysts which are capable to boost eNRR activity and concurrently suppress the overwhelming competitive hydrogen evolution reaction (HER). This work reports a new strategy to develop such catalysts to alleviate this challenge. This new strategy for the first time takes advantage of the outstanding capability of some redox active transition metal oxides (TMOs) in their super capability in electrochemically controlled proton interstitial doping and the associated remarkable structural changes to boost their NRR activity. Further, inspired by their unique hydrogen intercalation determined HER activity, this new strategy introduced cationic substitutional doping of the TMOs with nonmetal elements, such as phosphorus (P), to modulate their proton intercalation behavior, achieving HER suppression. In this work, tungsten oxide nanosheets (WO3) have been exploited as a typical example of such TMOs to demonstrate the feasibility of this innovative strategy. It is found that cationic P doping also accompanies introduction of large quantity of oxygen vacancies (OVs) in the matrix of the WO3 and structural changes of the WO3 lattice. The synergy of the substitutional doping and interstitial doping in tuning the electronic and the local geometric structures leads to significantly enhanced eNNR performance of WO3 nanosheets. An unprecedented high Faradaic efficiency (FE) of 64.1% with NH3 yield of 24.5 µg h-1 has been reached, representing the highest NRR performance for WO3 based catalysts. It is worth mentioning that the P-doped WO3 catalyst (200 nm square with a thickness of 20-40 nm) is much larger than most of the reported catalyst. The catalytic yield is even higher than that achieved with atomic thin two-dimensional (2D) WO3 nanosheets (OV-rich) catalysts (17 µg h-1 with a FE of 7.0%), which is known for their high catalytic efficiency due to the excellent accessibility of all the catalytic active sites. It is also worthwhile to mention that the FE of 64.1% is comparable to that of the natural nitrogenase can be reached (65%), which is unprecedented high compared to most of catalysts reported so far (<25%). In addition, inclusion of Li ions in the electrolyte further increased the NH3 yield to 60.1 µg h-1 with the high FE largely remained, reached the highest eNNR performance for all the TMO based catalysts. Density functional theory calculations further revealed the synergistic role of interstitial doping of H* and substitutional cationic doping of P, and the associated generation of OVs in increasing the electronic states crossing the Fermi level of the WO3 and thus reducing reaction energy barrier in N2 activation and hydrogenation. An interesting non-PCET (proton coupled electron transfer) mechanism is revealed in the first step and the rate determining step during eNNR, providing a new design principle for TMO-based catalysts. Figure 1

Synthesis and thermal analysis of nano-crystallite copper phosphate mixture and its composites as thermal energy conservation material in building coating

Synthesis and thermal analysis of nano-crystallite copper phosphate mixture and its composites as thermal energy conservation material in building coating

Electronic, thermodynamical and thermoelectric performances of RbSnI3 halide perovskite for photovoltaic cell and UV absorber applications

Thermoelectric materials are the best materials for energy conservation and its use in technological applications. In this context, the novel materials with multifunctional properties are constantly in demand. The perovskites are the best fit, with astounding multifunctional properties and applications in various areas. A methodical investigation of RbSnI3 (RSI) perovskite using density functional theory (DFT) under various exchange potentials (XCs) is reported. It exhibits metallic and semiconducting behavior in different XCs. The thermoelectric quantities such as Seebeck coefficient, conductivities, power factor, and figure of merit (ZT) under temperature, ranging from 0 to 1200 K, have been accounted. Interestingly, RSI exhibits ZT value of 0.77, which qualifies its application in thermoelectricity. Further, RSI has been investigated for various thermodynamic parameters under pressure, ranging from 0 to 50 GPa and temperature, ranging from 0 to 1200 K. RSI is found mechanically stable as well. The interaction of light with the material in terms of optical properties is reported. RSI exhibit good absorption in UV range. Consequently, RSI shows its potential applications in device manufacturing, photovoltaics, UV absorbers and energy generation.

Eco-friendly isolant composite mortars based on natural pozzolan, fly ash and plastic fibers

Thermal insulation in buildings has gained significant attention recently due to the clear benefits of selecting appropriate insulation materials for energy conservation. This study presents experimental research conducted to evaluate the thermal properties of mortar based natural Moroccan pozzolan and fly ash, both of which serve as alternatives to cement powder. Unlike cement, which requires energy-intensive extraction, natural pozzolan is an abundant volcanic material, and fly ash is a powdery residu generated as a byproduct during the combustion of coal in thermal power plants. The aim of this research is to explore the potential of these materials for thermal insulation and to address the environmental concern of plastic waste management through recycling. Twenty different mortar mixes were synthesized and evaluated, with a constant 10% of fly ash and varying percentages (10%, 20%, 30%, 40%) of natural pozzolan replacing cement. Additionally, 1% of plastic fibers based on the mortar volume were included. Thermal conductivity and heat capacity of the cured mortar mixtures were measured after 7 and 14 days using a TPS1500 hot disc Analyzer, which is currently the most precise and useful method for studying thermal transport parameters. To ensure consistent conditions, all samples were preconditioned to eliminate moisture before testing. The test results indicated the potential of using plastic fibers, fly ash, and natural pozzolan as effective thermal insulation materials. These materials demonstrated reduced thermal conductivity and increased specific heat capacity, making them desirable for building applications. From an economic and environmental standpoint, incorporating them as cement substitutes for sustainable cement production in thermal insulation is the most favorable approach.

Experimental Study on Horizontal Flame Spread of Dual-Flame Sources for Building Façade Energy Conservation FPU Foam Under the Effect of Lateral Wind

The thermal safety of building façade energy conservation materials is commonly affected by the wind in the surrounding environment. In addition, multiple fire sources might be formed because of the secondary ignition of the primary fire source. In this study, the competing effect of dual flame sources and the lateral wind speed (Uw=0m/s,0.5m/s,1.0m/s,1.5m/s,2.0m/s) on the typical characteristic parameters (flame morphology, mass loss rate, and heat transfer) of horizontal flame spread behavior of thermal insulation board flexible polyurethane was investigated through laboratory-scale experiments. The results showed that these parameters did not increase or decrease monotonously with the lateral wind speed. The original vertical flame front was stretched and tilted by the effect of lateral wind speed, which increased the area and thermal feedback of the preheating zone on the windward side. On the one hand, the lateral wind promoted the peak flame temperature and shortened the time to the peak temperature. On the other hand, the wind speed promoted the average flame spread velocity on the windward side and decreased the average flame spread velocity on the leeward side. The flame was blown out when the wind reached a critical speed. This could be well-explained with the mechanism of heat transfer and turbulent flow. This work can provide a reference for the fire rescue and building fire protection regulations.

Combustion and fire safety of energy conservation materials in building vertical channel: Effects of structure factor and coverage rate

Experimental study on combustion and fire safety of energy conservation materials (extruded polystyrene, i.e., XPS) in vertical channel with front openings of building façade is conducted, and effects of channel structure factor (α) and curtain wall coverage rate (β) are revealed. The XPS flame in the vertical channel is turbulent. There is a correlation between the flame height and pyrolysis length: xf=mxpn, where m and n vary with the change in structure factor and coverage rate. Upward flame spread rate decreases first and then increases as β rises. When 0≤β<0.2, the restraining effect of vertical channel on air entrainment dominates, while for 0.2≤β≤0.8, the heat feedback from curtain wall dominates. When β = 0, the influence of α on flame spread rate is not significant. The flame spread rate increases with increasing α when 0.2≤β≤0.8. A model is established to predict the flame spread rate under different coverage rates and structure factors. Compared with experimental results, the prediction error is smaller than 10%. Larger values of flame height and flame spread rate correspond to higher fire hazard. This work is beneficial for fire safety assessment of building thermal insulation materials and optimal design of energy-saving curtain wall.

Suitability Assessment and Experimental Characterization of Phase Change Materials for Energy Conservation in Indian Buildings

Abstract With increasing energy consumption in buildings, energy efficiency measures are matter of prime concern. A huge portion of energy consumed in buildings is used for regulating the thermal comfort. A solution to this is to incorporate phase change material (PCM) within the building elements which increases their overall thermal capacity. In the present study, the temperature of inner room surface, with and without PCM incorporation, is calculated for composite climate of Delhi. The analysis of PCM sandwiched walls has been performed. The performance analysis of five PCMs, having different melting temperatures, is carried out with nodal temperatures as the output. The results show that a phase change temperature range of 34–38 °C is suitable for peak summer conditions of Delhi. It is also observed that due to the low thermal conductivity of PCMs, they act as both storage medium and insulation, thus reducing temperature fluctuation during summer/winter. Based on the simulation, three PCMs were found suitable and hence were experimentally tested for their characteristic charging and discharging properties and performance, using differential scanning calorimeter (DSC). Based on the characterization results, it is concluded that two commercially available PCMs (Eicosane and OM35) are suitable for Delhi. All the other PCMs have also been simulated for different climatic conditions in India and their impact on heat gain has been assessed.

Development of Building Materials for Energy Conservation - Future Perspective

Development of Building Materials for Energy Conservation - Future Perspective

Development of a novel thermoelectric module based device for thermal stability measurement of phase change materials

Abstract A recently developed method for the thermal stability measurement of phase-change materials (PCMs) involves thermal cycling using a thermoelectric module as a heating and cooling element. However, the utility of this approach was found to have some limitations, mainly because the thermoelectric polarity is changed according to time rather than the actual sample temperature. A method for thermal cycling test, where the thermoelectric polarity is automatically changed according to the sample temperature was developed in this study. In addition, a new cartridge design in this device requires a small sample volume (1.53 cm3) and can be easily assembled and disassembled. This proposed device was tested on beeswax as a PCM sample. This is very important for savings PCMs material which usually expensive. The results showed that the apparatus had automatically cycled between the melting and cooling temperatures of beeswax. The thermal data showed that beeswax retains consistent melting and freezing temperatures after 1000 cycles, however, its heat of fusion degrades over repeated thermal cycling. This apparatus can be readily applied to study a wide range of PCMs for such as thermal energy storage materials for energy conservation. To our best knowledge, yet no study has been performed on this kind of equipment so far.

Sub-Atmospheric Pressure Coupled with Width Effect on Downward Flame Spread over Energy Conservation Material Polyurethane Foam

Rigid polyurethane (PUR) foam, a sustainable thermosetting building facade porous polymer material, has been widely applied in the construction industry for energy conservation. Additional knowledge of the fire safety performance of PUR foam at different altitudes and sample widths is required. Comparative lab-scale experiments were conducted in the Lhasa plateau (66.5 kPa) and the Hefei plain (99.8 kPa) in China. Flame propagation characteristics (average flame spread rate and flame height) were measured at different widths and atmospheric pressures of the test locations. Experimental results show that the dependence of dimensionless flame heights on sample width shows negative power law relationships with index of -w / 5.4 - -w / 5.8. Both flame height and flame spread rate were lower under low ambient pressure conditions as Hf ∝ P0.26~0.33 and Vf ∝ P0.057~0.568 Flame spread rate decreased with increasing sample width in the convection regime before a critical width of 4 cm – 8 cm, after which the flame spread rate increased in the radiation regime. Results of this study contribute to the science of combustion, fire safety and energy conservation, and provide a basis for fire safety protocols for historical heritage buildings in the Lhasa plateau.

Mechanical, acoustic, and thermal performances of shear thickening fluid–filled rigid polyurethane foam composites: Effects of content of shear thickening fluid and particle size of silica

ABSTRACTShear thickening fluid (STF) features a rheological property, and rigid polyurethane (PU) foams feature low thermal conductivity and excellent acoustic insulation. In this study, an STF/PU rigid foam composite sandwich structure was designed using different contents (0, 0.5, 1, or 1.5 wt %) of STF that contained 14 nm, 40 nm, or 75 nm silicon dioxide (SiO2). The effects of STF content and silica size on the cell structure, mechanical performance, acoustic absorption, and thermal performance of the STF/PU foam were explored. The test results show that STF/PU foam exhibited three characteristic acoustic absorption peaks, and the maximum acoustic absorption coefficient reached 0.841. STF addition increased compression, bending strength, and maximum acoustic coefficient, as well as initial mass loss temperature. STF‐filled PU foam composites containing 14 nm and 40 nm SiO2 had a mild rise in thermal insulation. The rigid STF/PU foam composites with a cell structure had the maximum thermal conductivity of 0.22 W m−1 K−1 and sound absorption coefficient of 0.841, which confirm that they are a good candidate for sound‐absorbing energy conservation materials. © 2019 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2019, 136, 47359.

Thermal and fire risk analysis of low pressure on building energy conservation material flexible polyurethane with various inclined facade constructions

This study investigated the factors affecting the fire safety analysis of the common construction material flexible polyurethane foam, based on combustion at various inclination angles and the ambient pressures at the altitudes of the cities of Hefei (99.8 kPa) and Lhasa (66.5 kPa). The effects of ambient air pressure, specimen width and inclination angle on the burning rate (as determined by mass loss), average flame spreading velocity, flame temperature and flame length were examined. The combustion rate was lower at 66.5 kPa and the wider specimens exhibited gradual spreading of the flame front in conjunction with melting and dripping. The burning rates at various inclinations were found to correlate with the pressure according to the expression ṁ∝pn,0.67<n<1.36, and this result can be explained based on pool fire theory. The average flame spreading velocity was found to correlate with pressure at various inclinations according to the relationship Va∝pn,2/3<n<1. The flame temperature was also observed to increase somewhat at the lower pressure, leading to an increase in the flame puffing frequency. Finally, a power law was used to describe the relationship between flame height and pressure, while a linear relationship was obtained between the index and the angle of inclination.

Vibration Analysis of Bilayered Graphene Sheets for Building Materials in Thermal Environments Based on the Element-Free Method

Graphene sheets are widely applied due to their unique and highly valuable properties, such as energy conservation materials in buildings. In this paper, we investigate the vibration behavior of double layer graphene sheets (DLGSs) in thermal environments which helps probe into the mechanism of energy conservation of graphene sheets in building materials. The nonlocal elastic theory and classical plate theory (CLPT) are used to derive the governing equations. The element-free method is employed to analyze the vibration behaviors of DLGSs embedded in an elastic medium. The accuracy of the solutions in this study is demonstrated by comparison with published results in the literature. Furthermore, a number of numerical results are presented to investigate the effects of various parameters (boundary conditions, nonlocal parameter, aspect ratio, side length, elastic foundation parameter, and temperature) on the frequency of DLGSs.

The State Defense Form Through Cultural Education On Energy Saving

&lt;p&gt;&lt;strong&gt;Abstract &lt;/strong&gt;–&lt;strong&gt; &lt;/strong&gt;A strong country is a nation that has a united citizen in defending, fighting and protecting&lt;strong&gt; &lt;/strong&gt;the country from all kinds of threats that occur, both military and non-military through awareness of defending the state for the integrity of the territory of Republic of Indonesia (NKRI). The concept of defending the state can be realized through energy-efficient culture education for the sustainability of Indonesia's energy in the future.&lt;/p&gt;&lt;p&gt;This article is intended to apply energy efficient and rational culture through the application of basic energy-saving values which include: (1) development of green education curriculum through energy conservation materials (efficient, wise and energy savvy); (2) developing the concept of energy-saving lifestyle habits in two directions (learning from student to student so that active student participation) such as turning off energy source equipment (tap water, lamp, AC) when they are not used continuously with assistance from educator which will become a positive habit that is embedded from childhood to use energy efficiently and rationally. The energy-saving culture education is not only a normative appeal, but there must be clear regulation on energy saving through cooperation between Ministry of Research and Technology and Ministry of Energy and Mineral Resources and Ministry of Defense. Therefore, the development culture of energy application continuously can be created with commitment from all academic society of education state defenses.&lt;/p&gt;&lt;p&gt;&lt;strong&gt;Keywords: &lt;/strong&gt;defending the state, energy conservation, education&lt;/p&gt;

Fire Hazards of Façade Materials for Energy Conservation under Flashover

Several fires had occurred in air-conditioned double-deck buses with energy-conserving façade foam materials in the past few years. Citizens in Hong Kong are now worrying whether they are safe while staying inside enclosures with energy-conserving foam materials. There are very few studies on evaluating the fire performance of façade materials. Solar heat gain control by using Overall Thermal Transfer Value in buildings would give shorter time to flashover. Flashover is hazardous in a room for fires with a sharp increase in burning rate and gas temperature. In this paper, nonlinear dynamics was used to study flashover in an example room using a two-layer zone model. A differential equation was set up to describe the rate of change of the layer temperature based on simple heat balance of the smoke layer. Evolution of the smoke layer temperature, equilibrium states of the system and their corresponding stabilities were then investigated.

Effect of Sample Width on Downward Flame Spread over Typical Energy Conservation Material at a High Elevation Area

An experimental study on downward flame spread over extruded polystyrene (XPS) foam at a high elevation is presented. The flame shape, flame height, mass loss rate and flame spread rate were measured. The influences of width and high altitude were investigated. The flame fronts are approximately horizontal. Both the intensity of flame pulsation and the average flame height increase with the rise of sample width. The flame spread rate first drops and then rises with an increase in width. The average flame height, mass loss rate and flame spread rate at the higher elevation is smaller than that at a low elevation, which demonstrates that the XPS fire risk at the higher elevation area is lower. The experimental results agree well with the theoretical analysis. This work is vital to the fire safety design of building energy conservation system.

Transparent conductive and infrared reflective AZO/Cu/AZO multilayer film prepared by RF magnetron sputtering

AZO/Cu/AZO multilayer films were prepared on glass substrate by radio frequency magnetron sputtering technology. The prepared films were investigated by a four-point probe system, X-ray diffraction, optical transmittance spectra, scanning electron microscope, atomic force microscopy and Fourier transform infrared spectroscopy. The results showed that Cu inner layer started forming a continuous film at the thickness around 11 nm. The prepared AZO/Cu/AZO samples exhibited the visible transmittance of 60–80 % and sample with 15 nm Cu inner layer showed the highest infrared reflection rate of 67 % in FIR region and the lowest sheet resistance of 16.6 Ω/sq. The proper visible transmittance and infrared reflection property of the AZO/Cu/AZO multilayer film make it a promising candidate for future energy conservation materials.

Analysis on Energy Conservation Materials’ Influence on Energy Saving Construction Cost

Engery-saving buildings are not always high-cost, the construction needs to consider not only the cost of construction, but also the consumption cost in use. We adopt new energy conservation materials and remarkable management mode to reduce the cost of energy-saving building, and fight to get the most benefit with the least investment, in order to master sovereignty in the fierce competition of energy-saving construction market, and to promote the sustainable development of energy-saving building.

Translating the Materials Genome Into Safer Consumer Products

Viewpoint pubs.acs.org/est Translating the Materials Genome Into Safer Consumer Products Oladele A. Ogunseitan, †,‡, * Jaime M. Allgood, †,‡ Stephanie C. Hammel, † and Julie M. Schoenung § Department of Population Health & Disease Prevention, Program in Public University of California, Irvine, California 92697-3957, United States School of Social Ecology, University of California, Irvine, California 92697, United States Department of Chemical Engineering & Materials Science, University of California, Davis, California 95616, United States perspective is missing in its research foci: sustainable materials intended for use in mass-marketed products must not threaten environmental quality and human health through their production, use or disposal. It is impossible to ignore the environmental pollution legacy of new materials that have revolutionized societal needs, including the accumulation of toxic waste from electronics products and plastics, which with and without phthalates, bisphenol A, or brominated flame-retardants, represented a remarkable commercial application of materials science and manufacturing, but now threaten to be the most highly contested products in legislation and environmental protection. Traditionally, the cost-benefit trade-offs inherent in selecting materials have not been transparent, leading to regrettable outcomes and policy reversals. This is because of incompatible metrics and weights that apply to different priorities such as energy conservation, economics, disease burden, and wildlife protection. To some extent, life cycle assessments (LCAs) can address trade-offs, but there are serious gaps in databases on which LCAs rely. For example, the poster on MGI features a fluorescent light bulb presumably to represent innovation in advanced materials for energy conservation. However, recent ive years after legislation to establish the Green Chemistry studies suggest that without developing appropriate waste Initiative (GCI), the landmark California Safer Consumer management methods for bulbs, the savings in energy may not Products Law became effective on October 1st, 2013. We justify their potential detrimental impacts. 4 argue here that the development of new regulatory policies to The existing federal law to reduce exposure to chemicals used stimulate the convergence of materials development research in commerce, the 1976 Toxic Substances Control Act, is widely and public health and environmental impact assessments considered a failure. Since its implementation, the U.S. EPA has provides evidence that these topics have traditionally addressed restricted only five chemicals. Recent efforts in the U.S. separate audiences, developed different values and measure- congress to reconfigure ToSCA have stalled through opposition ment systems, and focused on incompatible goals. The United from the chemical industry. These efforts include the “Safe State’s Materials Genome Initiative (MGI) provides an Chemicals Act of 2013” introduced in April 2013 by Senators opportunity to use lessons learned from the California Frank Lautenberg (D-NJ) and Kirsten Gillibrand (D-NY) that experience to reduce the temporal and scientific gaps that would require “safe-before-sell” evidence from manufacturers challenge initiatives to prevent disease and environmental and a version introduced on May 22, 2013 as the “Chemical pollution resulting from toxic chemicals in consumer products. Safety Improvement Act of 2013” by Senators Lautenberg and The MGI aims to more rapidly meet societal needs in clean David Viter (R-LA) to gain bipartisan support. 5 energy, national security, and human welfare by developing The acceleration of materials discovery under MGI should be materials that are “at the heart of innovation, economic accompanied by increased support for other research disciplines opportunities, and global competitiveness”. 2 The MGI calls for that curb human and environmental exposures to dangerous accelerating the pace of research in computational and chemicals will lead to costly and/or regrettable applications. experimental tools, collaborative networks, and digital data The MGI “challenges researchers, policy makers, and business processingall represent a boost for the fledgling discipline of leaders to reduce the time and resources needed to bring new materials informatics. Two years after MGI started, the National Institute of Standards and Technology, DoE, and the White House’s Office of Science called the first “Materials Received: September 13, 2013 Revised: October 6, 2013 Genome Initiative Grand Challenges Summit” (June 25−26, Accepted: October 11, 2013 2013). The agenda focused on five traditional materials science Published: October 30, 2013 themes. 3 The articulated MGI goals are laudable, but a crucial F © 2013 American Chemical Society dx.doi.org/10.1021/es4040864 | Environ. Sci. Technol. 2013, 47, 12625−12627