Rigid Polyurethane Foams Containing Modified Ammonium Polyphosphate Having Outstanding Charring Ability and Increased Flame Retardancy

Yang, Chunzhuang; Shao, Shuiyu

doi:10.3389/fmats.2021.712809

Cited by 13 publications

(11 citation statements)

References 46 publications

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“…From Figure 4 a, different parameters were determined to assess further the thermal performance of the formulations, and these are gathered in Table 6 . The onset temperature of degradation (T 5% ) did not show large differences between the formulations, except for the case of F_APP, for which the temperature was slightly higher and within the typical range for APP [ 74 ]. In fact, this formulation was the one that displayed the best thermal parameters.…”

Section: Resultsmentioning

confidence: 99%

Elaboration of Thermally Performing Polyurethane Foams, Based on Biopolyols, with Thermal Insulating Applications

De Hoyos-Martinez,

Mendez,

Martinez

et al. 2024

Polymers

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In this work, biobased rigid polyurethane foams (PUFs) were developed with the aim of achieving thermal and fireproofing properties that can compete with those of the commercially available products. First, the synthesis of a biopolyol from a wood residue by means of a scaled-up process with suitable yield and reaction conditions was carried out. This biopolyol was able to substitute completely the synthetic polyols that are typically employed within a polyurethane formulation. Different formulations were developed to assess the effect of two flame retardants, namely, polyhedral oligomeric silsesquioxane (POSS) and amino polyphosphate (APP), in terms of their thermal properties and degradation and their fireproofing mechanism. The structure and the thermal degradation of the different formulations was evaluated via Fourier Transformed Infrared Spectroscopy (FTIR) and thermogravimetric analysis (TGA). Likewise, the performance of the different PUF formulations was studied and compared to that of an industrial PUF. From these results, it can be highlighted that the addition of the flame retardants into the formulation showed an improvement in the results of the UL-94 vertical burning test and the LOI. Moreover, the fireproofing performance of the biobased formulations was comparable to that of the industrial one. In addition to that, it can be remarked that the biobased formulations displayed an excellent performance as thermal insulators (0.02371–0.02149 W·m−1·K−1), which was even slightly higher than that of the industrial one.

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Section: Resultsmentioning

confidence: 99%

Elaboration of Thermally Performing Polyurethane Foams, Based on Biopolyols, with Thermal Insulating Applications

De Hoyos-Martinez,

Mendez,

Martinez

et al. 2024

Polymers

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“…When the deformation degree exceeded 10%, the growth rate of foam compressive strength slowed down in the "platform" stage. 8,[56][57][58] When the deformation reached 40%, the foam gradually exceeded the tolerance limit, the cell wall deformed and even the foam collapsed. The stress-strain curve raised almost linearly.…”

Section: Mechanical Performance Test Of Rpufmentioning

confidence: 99%

Effect of microencapsulation flame retardant on flame retardancy and mechanical properties of rigid polyurethane foams

Peng,

Li,

et al. 2023

J of Applied Polymer Sci

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A microencapsulated flame retardant PMDOPO was synthesized by solution blending method using EGDMA as initiator and AIBN as cross‐linking agent. Rigid polyurethane foams were prepared in a one‐step process. PMDOPO was incorporated into the foams by blending with polycarbonate diols (PCDL) and foaming additives. The results of Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM) showed that PMDOPO was well formed and uniformly dispersed in the foam. The pore size and density of the foams first increased and then decreased with the addition of PMDOPO. X‐ray photoelectron spectroscopy (XPS), vertical combustion test, and thermogravimetric analysis (TGA) showed that the PMDOPO content was directly proportional to the flame retardancy and the thermal stability. The major weight loss shifted to higher temperature intervals. The amount of residual char of RPUF/PMDOPO‐25 was enhanced 50 times to 10.63% compared to pure RPUF. In addition, SEM and Raman analyses of the combustion residual char revealed that a phosphorus‐containing char layer was formed during thermal degradation. The dense charcoal layer helps to insulate heat and suppress combustion. The universal testing machine showed that RPUF with 15 wt% content had the best compression resistance, with an enhancement of 1.8 MPa over pure RPUF.

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“…Different methods have been reported to improve the flammability of RPUF such as halogenated flame-retardants [15], phosphorous flame-retardants [16,17], graphite [18], aluminum hydroxide [19], expandable graphite (EG) [20], melamine [21], coating [22,23] and other additive flame-retardants [13,24]. However, a high loading amount is often needed in order to achieve satisfactory flame-retardant effects, which leads to a decrease in the mechanical properties of the RPUF and increases the risk of secondary damage caused by the detachment of the building external wall [25][26][27]. There is a significant synergistic flame-retardant effect where excessive amounts of EG can be effectively avoided through the use of EG in combination with phosphorus/nitrogen-based flame-retardants, while the resulting mechanical and thermal insulation properties are significantly reduced compared to neat RPUF [25,[28][29][30][31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Balanced Thermal Insulation, Flame-Retardant and Mechanical Properties of PU Foam Constructed via Cost-Effective EG/APP/SA Ternary Synergistic Modification

Li,

Hou,

Liu

et al. 2024

Polymers

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To address the challenge of balancing the mechanical, thermal insulation, and flame-retardant properties of building insulation materials, this study presented a facile approach to modify the rigid polyurethane foam composites (RPUFs) via commercial expandable graphite (EG), ammonium polyphosphate (APP), and silica aerogel (SA). The resulting EG/APP/SA/RPUFs exhibited low thermal conductivity close to neat RPUF. However, the compressive strength of the 6EG/2APP/SA/RPUF increased by 49% along with achieving a V-0 flame retardant rating. The residual weight at 700 °C increased from 19.2 wt.% to 30.9 wt.%. Results from cone calorimetry test (CCT) revealed a 9.2% reduction in total heat release (THR) and a 17.5% decrease in total smoke production (TSP). The synergistic flame-retardant mechanism of APP/EG made significant contribution to the excellent flame retardant properties of EG/APP/SA/RPUFs. The addition of SA played a vital role in reducing thermal conductivity and enhancing mechanical performance, effectively compensating for the shortcomings of APP/EG. The cost-effective EG/APP/SA system demonstrates a positive ternary synergistic effect in achieving a balance in RPUFs properties. This study provides a novel strategy aimed at developing affordable building wall insulation material with enhanced safety features.

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Rigid Polyurethane Foams Containing Modified Ammonium Polyphosphate Having Outstanding Charring Ability and Increased Flame Retardancy

Cited by 13 publications

References 46 publications

Elaboration of Thermally Performing Polyurethane Foams, Based on Biopolyols, with Thermal Insulating Applications

Elaboration of Thermally Performing Polyurethane Foams, Based on Biopolyols, with Thermal Insulating Applications

Effect of microencapsulation flame retardant on flame retardancy and mechanical properties of rigid polyurethane foams

Balanced Thermal Insulation, Flame-Retardant and Mechanical Properties of PU Foam Constructed via Cost-Effective EG/APP/SA Ternary Synergistic Modification

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