Flame retardant performance of various UL94 classified materials exposed to external ignition sources

Hong, Sanghyun; Yang, Jungjin; Ahn, Seok-Ki; Mun, Yongik; Lee, Gyu-Cheol

doi:10.1002/fam.840

Cited by 28 publications

(21 citation statements)

References 6 publications

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“…The ground calcium carbonate (CaCO 3 ) was coated with stearic acid, and had an average particle size of 3.5 m (HI-PFLEX 100 from Specialty Minerals Inc.). The magnesium hydroxide (Mg(OH) 2 ) was a precipitated grade with an average particle size of 1.8 m (Vertex 60 from Huber). The nanoclay was a synthetic organo-magadiite prepared as described in Patent Cooperation Treaty Application Serial No.…”

Section: Methodsmentioning

confidence: 99%

“…In addition, theoretical char yields are included for two cases. In both the cases, the theoretical char yields assume silicone is converted to silica, ATH to Al 2 O 3 , Mg(OH) 2 to MgO, polymer to gaseous products, organomagadiite to inorganic magadiite. The two scenarios used to calculate theoretical char residue values shown in Figure 9 are: scenario (1) assuming that the CaCO 3 did not get hot enough to decompose, and scenario (2) assuming that the CaCO 3 was converted to CaO.…”

Section: Strongest Correlationsmentioning

confidence: 99%

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Correlations between pyrolysis combustion flow calorimetry and conventional flammability tests with halogen‐free flame retardant polyolefin compounds

2008

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SUMMARYSeven halogen-free flame retardant (FR) compounds were evaluated using pyrolysis combustion flow calorimetry (PCFC) and cone calorimetry. Performance of wires coated with the compounds was evaluated using industry standard flame tests. The results suggest that time to peak heat release rate (PHRR) and total heat released (THR) in cone calorimetry (and THR and temperature at PHRR in PCFC) be given more attention in FR compound evaluation. Results were analyzed using flame spread theory. As predicted, the lateral flame spread velocity was independent of PHRR and heat release capacity. However, no angular dependence of flame spread velocity was observed. Thus, the thermal theory of ignition and flame spread, which assumes that ignition at the flame front occurs at a particular flame and ignition temperature, provides little insight into the performance of the compounds. However, results are consistent with a heat release rate greater than about 66 kW/m 2 during flame propagation for sustained ignition of insulated wires containing mineral fillers, in agreement with a critical heat release rate criterion for burning. Mineral fillers can reduce heat release rate below the threshold value by lowering the flaming combustion efficiency and fuel content. A rapid screening procedure using PCFC is suggested by logistic regression of the binary (burn/no-burn) INTRODUCTIONTesting of flame retardant (FR) materials presents technical and scientific challenges. Various enduse applications have unique fire tests, which in most cases have not been correlated to small-scale methods of flammability assessment. To complicate matters further, these tests are often conducted on finished articles rather than pure polymer compounds. Limiting oxygen index (LOI) and cone calorimetry are among the most commonly cited methods for assessing flammability of FR polymer compounds. Although studies have raised questions about the reliability of LOI in flammability research [1, 2], LOI remains one of the most popular flammability test methods. This is likely due in large part to the fact that measurement of LOI can be done quickly using relatively inexpensive and simple equipment. Despite its popularity, correlation of LOI with performance in industry flame tests is limited, and application to predict burn behavior in actual fires is uncertain [3].Cone calorimetry is another method for flammability assessment of materials, and can be run on raw materials as well as fabricated articles, providing a wealth of data from measurement of a single specimen. While cone calorimetry is steadily gaining in popularity, its use outside of research remains limited due to a number of factors, including the high cost, complexity of cone calorimeters, and the resources required to operate and maintain them. Additionally, there is no widespread agreement in the industry about which parameters are most meaningful. Therefore, more studies correlating burn performance in key industry tests with results of cone calorimetry on compounds are needed.Cone calor...

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Section: Methodsmentioning

confidence: 99%

Section: Strongest Correlationsmentioning

confidence: 99%

Correlations between pyrolysis combustion flow calorimetry and conventional flammability tests with halogen‐free flame retardant polyolefin compounds

2008

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“…While and f ( ) are experimental data, and must be computed using Equations (3) and (4). In the following, we define characteristic values of the dependent variable (density function) from the area and moments of its history (distribution).…”

Section: Moments Of the Distributionmentioning

confidence: 99%

“…The specimens used for fire calorimetry tests are rarely thick enough to exhibit steady-state burning; hence, the only time-invariant HRR obtained from these typically thin and intermediate thickness specimens is the maximum/peak HRR and the test-average HRR. It is well known that the peak HRR of plastics measured in fire calorimeters under forced combustion correlates poorly with flame/ignition resistance [4,5]. However, steady HRR correlates flame retardancy [5,6] and is linked to combustion properties by a physical model [7,8].…”

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confidence: 99%

Steady heat release rate by the moment–area method

2007

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SUMMARYA simple mathematical procedure is described for computing temporal averages of heat release rate (HRR) data from the moments and area of the history. The moment-area method was used to calculate average The interpretation of heat release rate (HRR, W/m 2 ) histories obtained from bench-scale fire calorimeters is difficult because extrinsic factors such as sample thickness, orientation, and boundary conditions dominate the transient behavior and obscure the effect of material properties on the fire response [1][2][3]. The specimens used for fire calorimetry tests are rarely thick enough to exhibit steady-state burning; hence, the only time-invariant HRR obtained from these typically thin and intermediate thickness specimens is the maximum/peak HRR and the test-average HRR. It is well known that the peak HRR of plastics measured in fire calorimeters under forced combustion correlates poorly with flame/ignition resistance [4,5]. However, steady HRR correlates flame retardancy [5,6] and is linked to combustion properties by a physical model [7,8]. Consequently,

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“…The flammability of fire retarded (FR) styrene resins was studied in the context of monitor and TV housings [15]. UL94, Cone Calorimeter and limited oxygen index (LOI) benchscale data were compared to the qualitative burning of the housings when exposed to three different ignition n sources.…”

Section: Introductionmentioning

confidence: 99%

Full-scale flammability measures for electronic equipment

Bundy¹

2004

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Flame retardant performance of various UL94 classified materials exposed to external ignition sources

Cited by 28 publications

References 6 publications

Correlations between pyrolysis combustion flow calorimetry and conventional flammability tests with halogen‐free flame retardant polyolefin compounds

Correlations between pyrolysis combustion flow calorimetry and conventional flammability tests with halogen‐free flame retardant polyolefin compounds

Steady heat release rate by the moment–area method

Full-scale flammability measures for electronic equipment

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