Non-halogenated Flame Retardant Handbook. Группа авторов

Non-halogenated Flame Retardant Handbook - Группа авторов


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of changing extrusion lines is desirable. HDP has a phosphorus content of 10.8%, similar to BDP, hydrolytic stability and requires 8-12 wt.% loading in PC/ABS [321] and other PC based blends to achieve a V-0 rating. In talc filled PC only 7 wt. % HDP is needed for a V-0 rating [322].

      Resorcinol bis(di-2,6-xylyl phosphate) (RXP, Formula 2.26) [323] has been on the market for over 20 years, but mostly in Asia. Similar to HDP, RXP is mostly pure bisphosphate with very little oligomers present. Because of the specific chemical structure and high purity RXP is a solid with a melting point of 95°C. The steric hindrance provided by the 2,6-xylyl groups makes this product more hydrolytically stable than BDP. RXP has a phosphorus content of 9.0 % and its fire-retardant efficiency is similar to that of BDP; it provides a V-0 rating in PC/ABS at 12–16 wt. % loading [324] and about 7-10% wt. % loading in mineral filled PC/ABS [325].

      Academic studies [331, 332] on the mechanism of the flame-retardant action of aromatic phosphates in a PC based blend revealed that BDP shows mostly condensed phase action, RDP shows a mixed condensed phase and gas phase, whereas TPP is mostly gas-phase-active. This was attributed to the temperature of decomposition of PC and phosphates, e.g., TPP evaporates at a relatively low temperature and doesn’t have a chance to react with PC, whereas bisphosphates react with PC [333, 334]. RDP or BDP tend to cause PC to produce more char, decreasing the fuel supply to the flame and decreasing the flame temperature. TPP, which has gas phase activity, becomes more effective in the gas phase with a decrease in the flame temperature. HDP shows significant gas phase efficiency and when mixed with a mostly condensed phase active BDP exhibits a synergistic effect [335]. Another study showed [336] that the hindered structure of RXP slows down the reaction with PC and therefore it shows less condensed phase action compared to RDP. Interestingly talc improves the flame retardant efficiency of bisphosphates because of the better protective properties of the char [337] and on the other hand glass fiber reinforcement deteriorates the flame retardant efficiency because it increases the combustion surface (candlewick effect) [338].

      Commercial PPE/HIPS blends, also known as modified PPE, contain from 35 to 65 wt. % PPE. Similarly to PC/ABS, the first FR used in PPE/HIPS was TPP, which was later replaced with RDP and BDP [340]. Typically, between 9 and 15 wt. % of a phosphate ester is needed to achieve V-0 rating; the lower the PPE content in the blend, the higher the phosphate loading required. PTFE is required to prevent dripping. A copolymer of polydimethyl- and polydiphenyl siloxane can prevent dripping and is at the same time synergistic with RDP [341]. Addition of polysiloxane also helps to decrease smoke formation allowing the achievement of HL3 rating in the European mass transit test EN 45545 in PPE/HIPS based glass fiber composites [342]. Apart from flame retardancy, phosphate esters also play an important role in plasticization and resin flow improvement. Therefore, some phosphate esters can be added to PPE/HIPS even if flame retardancy is not needed. Because PPE is not sensitive to hydrolysis, any bisphosphate can be used in high humidity applications, as for example water pipes [343].

      Apart from HIPS, PPE is also compatible with styrene based thermoplastic elastomers, such as styrene-ethylene-butylene-styrene (SEBS) block copolymer. A copolymer of SEBS and maleic anhydride is used as a compatibilizer [344]. These blends are mostly used in electric wire jackets and often polyolefins and HIPS are also included in the blends. As the patent literature indicates, aromatic bisphosphates RDP [345] and BDP [346] were originally used as flame retardants in PPE/SEBS blends. Bisphosphates are very compatible and soluble in PPE, but not in TPEs and polyolefins and therefore the total loading of bisphosphates is limited because of potential exudation. To overcome this problem in blends containing less than 50% PPE, solid flame retardants are added along with bisphosphates. The patent literature shows combinations of aromatic phosphates with magnesium hydroxide [347], melamine phosphates [348], ammonium polyphosphate [349] or DEPAL [350].

      Another use of aromatic bisphosphates is in TPU. One of the common commercial halogen-free TPU formulations is based on about 25 wt. % melamine cyanurate and 5 wt. % RDP [356]. This TPU still drips, but the droplets do not ignite cotton and therefore it is rated V-0. Addition of some free isocyanate during processing creates additional cross-links and prevents dripping [357]. Many formulations based on RDP and ATH passing the VW-1 rating in the UL-1581 test for wire and cables applications were developed [358] and some were probably commercialized. Interestingly, the addition of only 2.5 wt. % novolac type epoxy resin


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