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³¤°²´óѧѧ±¨£¨×ÔÈ»¿Æѧ°æ£©[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2019Äê02ÆÚ

Page:

47-56

Research Field:

µÀ·¹¤³Ì

Publishing date:

Info

Title:

Flameª²retardant mechanism of flameª²retardant asphaltª¤based on thermal analysis

Author(s):

XIONG Jianª²pingª¬ª©1; 2ªª;  PENG Wenª²juª¬3;  CHEN Yuª¬4;  XU Weiª²anª¬1

£¨1. Guangxi Key Lab of Road Structure and Materials, Guangxi Transportation Research & Consultingª¤CO., LTD., Nanning 530007, Guangxi, China; 2. Postdoctoral Workstation, Guangxi Communicationsª¤Investment Group CO., LTD., Nanning 530028£¬ Guangxi, China; 3. Centralª²Southern Safety &ª¤Environment Technology Institute CO., LTD., Wuhan 430051, Hubei, China£» 4. Guangxi Beibu Gulfª¤Investment Group CO., LTD., Nanning 530028, Guangxi, China £©

Keywords:

road engineering;  flameª²retardant asphalt;  thermal analysis;  mechanism

PACS:

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DOI:

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Abstract:

To study the flameª²retardant mechanism of flameª²retardant asphalt, a base asphalt, single flameª²retardants, composite flameª²retardants, flameª²retardant asphalt, and warmª²mix flameª²retardant asphalts which made by the two flameª²retardants were studied£¬ based on a comprehensive thermal analysis method. The three single flameª²retardants were considered as follows£¬ decabromodiphenyl ethane (DBDPE), antimonous oxide (Sbª­2Oª­3), and aluminum hydroxide (ATH). The two composite flameª²retardants applied were a selfª²developed DBDPEª²Sbª­2Oª­3 flameª²retardant and a DBDPEª²Sbª­2Oª­3ª²ATH flameª²retardant. The flameª²retardant asphalts were prepared by mixing the base asphalt and flameª²retardants using a highª²speed shearing machine. The warmª²mix flameª²retardant asphalt was prepared by adding a Sasobit warmª²mixed agent to the composite flameª²retardant asphalt. By comparing and analyzing thermogravimetric £¨TG£©, thermogravimetric derivative£¨DTG£©, differential thermal analysis£¨DTA£©, and other thermal analysis curves of various samples, a flameª²retardant mechanism that adding a flameª²retardant and a warmª²mix agent into the asphalt was presented. The results show that DBDPE is dominated by the gasª²phase flameª²retardant mechanism, and the flame retardance in a solid phase also plays a role. Hydrogen bromide£¨HBr£©gas is produced, consuming free pyrolysis radicals from the asphalt and restraining the combustion process of the asphalt. Sbª­2Oª­3 forms a blanket effect through sublimation heat absorption and steam formation at approximately 600 ¡æ, which acts as a gas flameª²retardant. Sbª­2Oª­3 and DBDPE achieve a good coª²effective flameª²retardant mechanism, and the heat curve slope of the Sbª­2Oª­3ª²DBDPE flameª²retardant asphalt decreases significantly compared with the base asphalt. ATH mainly shows a heatª²absorbing flameª²retardant mechanism. The Alª­2Oª­3 generated by ATH has a condensed phase flameª²retardant effect and an antiª²smoking effect. The flameª²retardant effect of ATH under the conditions of a low dosage (less than 8%, mass fraction, the same below) is not clear. However, it can enlarge the flameª²retardant temperature range of the DBDPEª²Sbª­2Oª­3 composite flameª²retardant and effectively promote a carbonizing reaction of the asphalt. The initial decomposition temperature of the DBDPEª²Sbª­2Oª­3ª²ATH composite flameª²retardant asphalt is similar to that of the base asphalt, although the final decomposition temperature increases by approximately 100 ¡æ and retains ª©16.5%ªª of the carbon residue. Therefore, the DBDPEª²Sbª­2Oª­3ª²ATH composite flameª²retardant shows a good flameª²retardant effect. Sasobit is able to inhibit the carbonated reaction of the asphalt and has an adverse effect on the flameª²retardant effect of the DBDPEª²Sbª­2Oª­3ª²ATH flameª²retardant. 3 tabs, 15 figs, 21 refs.

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Last Update: 2019-04-01