化工学报
化工學報
화공학보
CIESC Jorunal
2015年
10期
4202-4210
,共9页
朱军峰%李元博%张光华%王睿
硃軍峰%李元博%張光華%王睿
주군봉%리원박%장광화%왕예
梳型聚羧酸盐%侧链长度%流变%吸附%分散%水煤浆
梳型聚羧痠鹽%側鏈長度%流變%吸附%分散%水煤漿
소형취최산염%측련장도%류변%흡부%분산%수매장
comb-like polycarboxylate%side chain length%rheology%adsorption%dispersion%coal-water slurry
合成了一系列具有不同侧链长度的梳型聚羧酸盐(PC),研究了PC侧链长度对水煤浆的分散和流变性能的影响,使用X射线光电子能谱(XPS)分析了PC在煤水界面的吸附,并结合水煤浆Zeta电位及PC对煤颗粒的润湿性探讨了 PC 的分散作用机理,为设计制得高效的聚羧酸盐水煤浆分散剂提供依据。结果表明:长主链、短侧链和高阴离子基团含量的PC500(侧链聚合度n=11)具有优良的分散性,所制水煤浆属假塑性流体。PC在煤表面呈单分子层吸附,其中PC500的吸附密度和吸附厚度均最大,分别为0.638 mg·m?2和4.20 nm,其对煤粒润湿性也较好,所制水煤浆Zeta电位绝对值最高。侧链长度适中的PC500通过平衡吸附层厚度与Zeta电位发挥空间位阻和静电斥力作用分散水煤浆,其可有效地降低水煤浆Gibbs能,使煤粒间“团聚”减弱,浆体分散性提高。
閤成瞭一繫列具有不同側鏈長度的梳型聚羧痠鹽(PC),研究瞭PC側鏈長度對水煤漿的分散和流變性能的影響,使用X射線光電子能譜(XPS)分析瞭PC在煤水界麵的吸附,併結閤水煤漿Zeta電位及PC對煤顆粒的潤濕性探討瞭 PC 的分散作用機理,為設計製得高效的聚羧痠鹽水煤漿分散劑提供依據。結果錶明:長主鏈、短側鏈和高陰離子基糰含量的PC500(側鏈聚閤度n=11)具有優良的分散性,所製水煤漿屬假塑性流體。PC在煤錶麵呈單分子層吸附,其中PC500的吸附密度和吸附厚度均最大,分彆為0.638 mg·m?2和4.20 nm,其對煤粒潤濕性也較好,所製水煤漿Zeta電位絕對值最高。側鏈長度適中的PC500通過平衡吸附層厚度與Zeta電位髮揮空間位阻和靜電斥力作用分散水煤漿,其可有效地降低水煤漿Gibbs能,使煤粒間“糰聚”減弱,漿體分散性提高。
합성료일계렬구유불동측련장도적소형취최산염(PC),연구료PC측련장도대수매장적분산화류변성능적영향,사용X사선광전자능보(XPS)분석료PC재매수계면적흡부,병결합수매장Zeta전위급PC대매과립적윤습성탐토료 PC 적분산작용궤리,위설계제득고효적취최산염수매장분산제제공의거。결과표명:장주련、단측련화고음리자기단함량적PC500(측련취합도n=11)구유우량적분산성,소제수매장속가소성류체。PC재매표면정단분자층흡부,기중PC500적흡부밀도화흡부후도균최대,분별위0.638 mg·m?2화4.20 nm,기대매립윤습성야교호,소제수매장Zeta전위절대치최고。측련장도괄중적PC500통과평형흡부층후도여Zeta전위발휘공간위조화정전척력작용분산수매장,기가유효지강저수매장Gibbs능,사매립간“단취”감약,장체분산성제고。
Comb-likepolycarboxylate dispersants (PC) with different side chain lengths ranging from 8—23 nm were synthesized using esterifiedmacromer of methoxypolyethyleneglycol (MPEG)-acrylic acid (AA), AA and styrene sulfonic sodium (SSS). The molecular structure of PC was analyzed by testing its anionic group content and relative molecular. Experiments were performed to study the influence of the length of PC side chain on dispersion and rheological properties of coal water slurry (CWS). The adsorption behaviors of PC on coal/water interface were analyzed by X-Ray photoelectron spectroscopy (XPS), which was combined with the Zeta potential and the wettability of PC on coal to investigate the action mechanism of PC dispersions in order to provide the basis for designing more efficient polycarboxylate dispersants. The results showed that the dispersibility of PC500 (n=11) was the best due to its structure of long main chain, short side chains and high anionic group content. The CWS using comb-like PC was represented as pseudoplastic fluid, which was best matched with Herschel-Bulkley model. The monolayer adsorption of PC500 on the coal surface possessed the highest adsorption density (0.638 mg·m?2) as well as the maximum thickness (4.20 nm) with better wettability and the highest Zeta potential on coal. PC500 wearing the proper length of the side chain played the steric hindrance and electrostatic repulsion to disperse CWS by balancing adsorption thickness and Zeta potential. PC500 with the right length of the side chain can reduce Gibbs of CWS to weaken “reunion” among the coal particles while improving dispersibility of CWS.
