Effect of Cross-Linker Length on the Absorption Characteristics of the Sodium Salt of Cross-Linked Polyaspartic Acid.

For the development of biodegradable superabsorbent polymers, the effect of the cross-linking length on the absorption characteristics of the Na salt of polyaspartic acid (PAspNa) was demonstrated using different concentrations of diamine cross-linking agents bearing carbon chains of different lengths, viz., ethylenediamine, 1,6-hexamethylenediamine, 1,8-diaminooctane, 1,10-diaminodecane, and 1,12-diaminododecane were used as cross-linking agents. The absorption of PAspNa was measured in deionised water and in a 0.9% aqueous NaCl solution. Under the conditions tested, when the alkyl chain of PAspNa was too short or too long, the absorbency was low and the cross-linking length was optimum. The success of the cross-linking reaction was confirmed by FT-IR spectroscopy. The degree of cross-linking was estimated and the ideal concentration for maximum water absorption was determined by elemental analysis. The sample obtained by cross-linking 1,8-diaminooctane at a concentration of 0.11 g/g polysuccinimide (PSI) showed the highest absorption. The thermal properties of each material were determined by dynamic scanning calorimetry. Therefore, the length of the cross-linking agent was found to strongly influence water absorption.

Effect of aluminized fabrics on radiant protective performance of fire proximity suit materials.

Radiant heat may be a significant component of heat exposure in the case of proximity firefighting. To combat high levels of radiant heat, fire proximity suits made of aluminized fabrics (Al-Fb) are commonly used due to their proven radiant protective performance (RPP). In this study RPP of various Al-Fb prepared using different aluminized films (Al-Fl) such as double-sided aluminized film and single-sided aluminized film and different base fabrics such as woven, knit, and nonwoven fabrics are compared. The effect of flexing on RPP and flame protective performance (FPP) of Al-Fb is also examined. The results show that RPP of Al-Fl is affected by the protective film to protect against mechanical or physical damages, and also by their structure such as whether the second reflective aluminum layer is present or not. In addition RPP of Al-Fb is also influenced by the base fabric, especially its surface roughness. The increased surface roughness combined with the damage caused to the aluminum layer after flexing result in reduction of RPP of Al-Fb. The contribution of Al-Fl to FPP of Al-Fb is not as significant as to RPP. Finally, based on the results, some points that may be important in developing and designing fire proximity suits are recommended.