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Preparation and characterization of flame retardant n
Flame retardant n-hexadecane/silicon dioxide (SiO (2)) composites as thermal energy storage materials were prepared using sol-gel methods. In the
Preparation of a novel PEG composite with halogen-free flame retardant supporting matrix for thermal energy storage
DOI: 10.1016/J.APENERGY.2012.12.070 Corpus ID: 109318836 Preparation of a novel PEG composite with halogen-free flame retardant supporting matrix for thermal energy storage application In this paper, a novel and efficient halogen-free flame retardant, HGM
Flame retardant composite phase change materials with MXene
Preparation of CPCM containing PEG, EG, MXene and FR (APP:ZHS = 2:1) was achieved using a melt blending technique, as illustrated in Fig. 1, the pure PEG was put into a beaker in an oven at 100 C for 30 min until it melted, followed by addition of predetermined amount of MXene and EG with stirring for 30 min, the flame retardant
Flame-retardant composite phase change material with silicone
Herein, the novel multifunctional CPCM with paraffin (PA), epoxy resin (ER), expanded graphite (EG), methyl MQ silicone resin (MQ) and melamine phosphate (MP)
Sustainable, heat-resistant and flame-retardant cellulose-based
A sustainable, heat-resistant and flame-retardant cellulose-based composite nonwoven has been successfully fabricated and explored its potential
Preparation and characterization of flame retardant n
Flame retardant n-hexadecane/silicon dioxide (SiO 2) composites as thermal energy storage materials were prepared using sol–gel methods. In the
Flame-Retardant Crosslinked Polymer Stabilizes
Here, a fire-resistant polymer crosslinked with ammonium polyphosphate (APP) and polyacrylic acid (PAA) to improve the electrochemical properties and enhance the safety of the GSC anode is
(PDF) Synergistic effects between red phosphorus and alumina trihydrate in flame retardant silicone rubber composites
Zhuo et al. [5] prepared silicone rubber/ATH composites with red phosphorus as a flame retardant; they found that a high content of red phosphorus led to significant improvements in flame
Polymers | Free Full-Text | Flame Retardancy and
A novel phosphorus-silicon flame retardant (P5PSQ) was prepared by bonding phosphate to silicon-based polysilsesquioxane (PSQ) and used as flame retardant of poly (lactic acid) (PLA). The
Preparation of halogen-free flame retardant hybrid paraffin composites as thermal energy storage
Flame retardancy of silicone-based materials Polymer Degradation and Stability, 94 (2009), pp. 465-495 Preparation and properties of palmitic acid/SiO 2 composites with flame retardant as thermal energy storage materials Solar Energy Materials and Solar,
Metal–Organic Frameworks–Based Flame-Retardant System for
The modification strategies and flame retardant efficiency of MOFs-based flame retardants are analyzed with special emphasis on the flame retardant mechanisms of different components. In addition, most MOFs-based flame retardant composites exhibit multiple functions that benefit from their inherent properties such as wave absorption as
Fabrication and Characterization of Flame-Retardant Nanoencapsulated n -Octadecane with Melamine–Formaldehyde Shell for Thermal Energy Storage
In conclusion, this nanoencapsulated n-octadecane with an excellent phase change properties and flame-retardant properties exhibit considerable potential for energy saving construction
Sodium Silicate/Urea/Melamine Ternary Synergistic Waterborne Acrylic Acid Flame-Retardant Coating and Its Flame-Retardant
The predominant approach to fabricating flame-retardant waterborne acrylic coatings involves incorporating flame retardants into the coatings. Flame retardants are categorized into inorganic and organic types based on their chemical composition [], with inorganic flame retardants being more extensively researched and applied.. Among
Flame retardant composite phase change materials with MXene for lithium-ion battery thermal management systems,Journal of Energy Storage
Flame retardant composite phase change materials with MXene for lithium-ion battery thermal management Journal of Energy Storage ( IF 9.4) Pub Date : 2024-03-14, DOI: 10.1016/j.est.2024. Yuqi Wang, Luyao Zhao, Wang Zhan, Yin Chen, Mingyi Chen
Preparation and characterization of flame retardant n-hexadecane/silicon dioxide composites as thermal energy storage
Flame retardant n-hexadecane/silicon dioxide (SiO(2)) composites as thermal energy storage materials were prepared using sol-gel methods. In the composites, n-hexadecane was used as the phase change material for thermal energy storage, and SiO(2) acted as the supporting material that is fire resistant.
Flame-retardant composite phase change material with silicone
Bio-based poly (glycerol-itaconic acid)/PEG/APP as form stable and flame-retardant phase change materials. Composites Communications 30: 101057. DOI: 10.1016/j co.2022.101057. View in Article CrossRef Google Scholar [35] Feng, J., Liu, L
Thermal stability, latent heat and flame retardant properties of the thermal energy storage phase change materials
The DSC measurements indicated that the additives of flame retardant had little effect on the temperatures of phase change peaks and thermal energy storage property. The TGA results showed that the loadings of the EG and APP increased the temperature of the maximum weight loss and the charred residue of the PCM composites
Reprocessable Flame Retardant Silicone Polyurethane Based on
We endow the material excellent flame retardance and reprocessing properties respectively, which holds great promise for fire safety behavior and
Preparation and characterization of flame retardant n
Flame retardant n-hexadecane/silicon dioxide (SiO(2)) composites as thermal energy storage materials were prepared using sol-gel methods. In the composites, n
Preparation and characterization of flame retardant n-hexadecane/silicon dioxide composites as thermal energy storage
Flame retardant n-hexadecane/silicon dioxide (SiO 2) composites as thermal energy storage materials were prepared using sol–gel methods. In the composites, n -hexadecane was used as the phase change material for thermal energy storage, and SiO 2 acted as the supporting material that is fire resistant.
Battery thermal safety management with form-stable and flame
We demonstrated that addition of a porous network structure of EG as a shaping support to increase PA''s thermal conductivity, and incorporation of
Thermal Runaway of Lithium-Ion Batteries Employing Flame-Retardant Fluorinated Electrolytes
1 Introduction The demand for high-energy-density lithium-ion batteries (LIBs) is ever increasing with the growth of the electric vehicle (EV) market. [1-3] The driving range of EVs breaks through 500 km [1, 4] thanks to commercialization of high-capacity electrode materials, for example, layered Ni-rich Li(Ni x Mn z Co y)O 2 (NMCxyz, x ≥ 0.6).
Preparation and characterization of flame retardant n-hexadecane/silicon dioxide composites as thermal energy storage
DOI: 10.1016/j.jhazmat.2010.05.114 Corpus ID: 21422198 Preparation and characterization of flame retardant n-hexadecane/silicon dioxide composites as thermal energy storage materials. @article{Fang2010PreparationAC, title={Preparation and characterization of
Preparation of a novel PEG composite with halogen-free flame retardant supporting matrix for thermal energy storage application
Fig. 1 shows solid state 31 P NMR spectrum of PEG composite. There is only one peak occurs in this spectrum, showing the typical phosphamide structure, which was very stable during the sol–gel process in basic condition [32].The 31 P NMR peak value of PEG composite moved to upfield, leading to 14.7 ppm (compared with 17.6 ppm of 31
Preparation of three-dimensional modified boron nitride and its effect on the flame-retardant performance and thermal conductivity of silicone
Characterization of flame retardants The structure and morphology of BN and BN-β-FeOOH were directly observed by SEM, and the element composition of BN-β-FeOOH was analyzed by EDX, as shown in Fig. 1 gure 1 shows that BN has a lamellar structure, while the rods grown on the surface of BN-β-FeOOH are β-FeOOH, and
Fire behaviour of EPDM/NBR panels with paraffin for thermal energy storage
In order to improve the fire resistance, two selected flame retardants (FRs) were dispersed both in the EPDM core and in the NBR envelope. In this work, the combustion residues from cone calorimeter tests were analysed by various techniques to explain the combustion mechanisms and the interaction of FRs.
Thermal stability, latent heat and flame retardant properties of the thermal energy storage phase change materials
DOI: 10.1016/J.RENENE.2009.01.017 Corpus ID: 110678801 Thermal stability, latent heat and flame retardant properties of the thermal energy storage phase change materials based on paraffin/high density polyethylene composites @article{Cai2009ThermalSL
Thermal management ability and flame retardancy of silicone rubber foam filled with flame retardant
A novel nano phase change capsules (M-EPCM) with flame retardant performance was prepared by introducing LDH. • The introduction of 18 wt% M-EPCM can significantly improve the thermal regulation capacity of silicone rubber foam (SRF). •
Flame-retardant wood-based composite phase change materials based on PDMS/expanded graphite coating for efficient solar-to-thermal energy storage
The flame-retardant wood-based composite PCMs have been found to possess favorable characteristics in terms of phase change temperature (30–32 C), high energy storage capacity, excellent thermal reliability even after undergoing 100 heating-cooling cycles
A novel flexible flame-retardant phase change materials with
The use of flame-retardant surface treatment can effectively prevent future material combustion by positioning all flame-retardant materials where the chain reaction is most likely to be stopped. Fig. 15 (f) and (g) show that FRC begins to degrade at around 300 °C, at which point it starts to operate as a flame retardant.
Application of Polyethylene Glycol-Based Flame-Retardant
Composite phase change materials commonly exhibit drawbacks, such as low thermal conductivity, flammability, and potential leakage. This study focuses on the development of a novel flame-retardant phase change material (RPCM). The material''s characteristics and its application in the thermal management of lithium-ion batteries are
Mechanically Robust and Flame-Retardant Silicon Aerogel
In this work, we report the synthesis of silicon aerogel elastomers (SAEs) by one-pot hydrolytic condensation of silanes, followed by drying at room temperature. The as-synthesized SAE features excellent flexibility and mechanical robustness, for example, a high compressive strength of up to 40 kPa at 75% strain was achieved. Combined with
Leakage Proof, Flame-Retardant, and Electromagnetic Shield Wood Morphology Genetic Composite Phase Change Materials for Solar Thermal Energy
Phase change materials (PCMs) offer a promising solution to address the challenges posed by intermittency and fluctuations in solar thermal utilization. However, for organic solid–liquid PCMs, issues such as leakage, low thermal conductivity, lack of efficient solar-thermal media, and flammability have constrained their broad applications. Herein, we present an
Fabrication of flame-retardant phase-change materials for photo-to-heat conversion and flame-retardant
In this study, phosphorus-modified hexadecanol is used as an energy storage medium for flame-retardant FSPCMs owing to its high latent heat and thermal stability [25]. It also exhibits a notable synergistic effect with an FR (1-oxo-4-hydroxymethyl-2,6,7-trioxa-l-phosphabicyclo[2.2.2]octane; PEPA) and a carbon-forming agent
Fire Retardant Phase Change Materials—Recent Developments
Hence, Fang et al. [] applied the sol-gel method to prepare palmitic acid/silicon dioxide (SiO 2) thermal energy storage composite materials with melamine as a flame retardant. Palmitic acid was homogenously dispersed in the porous network of SiO 2 due to the capillary and surface tension forces.
Flame-Retardant Crosslinked Polymer Stabilizes
Advanced Energy Materials is your prime applied energy journal for research providing solutions to today''s global energy challenges. Abstract The graphite–silicon composite (GSC) anode materials with