«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶¼¯ÃÀ´óѧѧ±¨£¨×ÔÈ»¿Æѧ°æ£©¡·[ISSN:1007-7405/CN:35-1186/N]

¾í:

µÚ27¾í

ÆÚÊý:

2022ÄêµÚ5ÆÚ

Ò³Âë:

439-446

À¸Ä¿:

´¬²°Óë»úе¹¤³Ì

³ö°æÈÕÆÚ:

2022-09-28

ÎÄÕÂÐÅÏ¢/Info

Title:

Comparison of Two Improved Algorithms for Determining Pore Size Distribution of Activated Carbon Based on CDFT

×÷Õß:

Öì×ÓÎÄ; Ö£³¬è¤; ¶¡µÂ·æ; Ö£ÇàéÅ; ³ÂÇìÅô

£¨¸£½¨Ê¡´¬²°Ó뺣Ñ󹤳ÌÖصãʵÑéÊÒ£¬¼¯ÃÀ´óѧÂÖ»ú¹¤³ÌѧԺ£¬¸£½¨ ÏÃÃÅ 361021£©

Author(s):

ZHU Ziwen; ZHENG Chaoyu; DING Defeng; ZHENG Qingrong; CHEN Qingpeng

(Provincial Key Laboratory of Naval Architecture & Ocean Engineering£¬School of Marine Engineering£¬ª¤Jimei University£¬Xiamen 361021£¬China)

¹Ø¼ü´Ê:

»îÐÔÌ¿; Îü¸½; ¿×¾¶·Ö²¼; ¸Ä½øËã·¨; ¾­µäÃܶȷºº¯ÀíÂÛ

Keywords:

adsorption; activated carbon; pore size distribution; algorithm; classical density functional theory

·ÖÀàºÅ:

-

DOI:

-

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

ΪÁËÌá¸ß¾­µäÃܶȷºº¯ÀíÂÛCDFT£¨classical density functional theory£©ÔÚÔ¤²â»îÐÔÌ¿¿×¾¶·Ö²¼Ê±µÄ׼ȷÐÔ£¬±È½ÏÁËÁ½ÖÖ»ùÓÚ»îÐÔÌ¿¿×±Ú±íÃæ´Ö²Ú¶ÈÓ°ÏìµÄCDFT¸Ä½øËã·¨¡£½áºÏÏÁ·ì¿×±ÚÉÏÏàͬµÄ̼ԭ×ÓÃܶȷֲ¼£¬·Ö±ðÀûÓÃƽ»¬ÃܶȽüËÆ£¨SDA£©ºÍ»ù±¾²âÁ¿ÀíÂÛ£¨FMT£©Çó½â¶þÔªÁ÷Ìå»ìºÏ̬µÄ¹ýÊ£×ÔÓÉÄÜÕ¹¿ªÏ²¢Ô¤²âë²ÆøÔÚ·Çʯī»¯Ì¿ºÚBP280ÉϵÄÎü¸½Æ½ºâ¡£¸ù¾Ý87.3 KÏ»îÐÔÌ¿Îü¸½ë²ÆøµÈÎÂÏߣ¬È·¶¨²»Í¬¿×¾¶µÄÀíÂÛµÈÎÂÏߺ˺ó£¬ÀûÓÃÓÅ»¯º¯Êý¼ÆËã»îÐÔÌ¿¿×¾¶ÔÚ0.35~12 nmµÄ·Ö²¼¡£½á¹û±íÃ÷£¬MNLDFTËã·¨Ô¤²â¿×¾¶·Ö²¼¾ßÓÐÁ¬Ðø·Ö²¼ÐÔ£¬»îÐÔÌ¿µÄ±È±íÃæ»ýΪ1252.63 m2/g£»QSDFTËã·¨²â¶¨µÄPSD(pore size distribution)ÔÚ1 nm´¦¾ßÓжϵ㣬²â¶¨µÄ»îÐÔÌ¿±È±íÃæ»ýΪ1431.64 m2/g£¬ÕâÒ»½á¹ûÓëͨ¹ýBET·½·¨È·¶¨µÄ±È±íÃæ»ý1445 m2/g½Ó½ü¡£ÔËÓÃQSDFTÀ´±íÕ÷»îÐÔÌ¿¿×¾¶·Ö²¼¸üºÏÀí¡£

Abstract:

In order to improve the accuracy of classical density functional theory (CDFT) while predicting pore size distribution (PSD) of activated carbon, two CDFT algorithms based on the assumption on the influence of surface roughness of activated carbon pore walls were compared in this paper. The same density distribution of carbon atoms on the walls of the slit pores were supposed, the excess free energy of the mixed state of the binary fluid and the adsorption equilibrium of argon on nonª²graphitized carbon black BP280 were then determined by smooth density approximation (SDA) and fundamental measure theory (FMT), which is respectively denoted as MNLDFT and QSDFT. The theoretical isotherm kernels of different pore sizes were calculated based on the isotherms of argon at 87.3 K by combining two improved algorithms, the optimization function was employed to determine the PSD of activated carbon within the range of 0.35-12 nm. Results show that the PSD predicted by MNLDFT is in a continuous distribution with a specific surface area about 1252.63 m2/g, and the PSD determined by QSDFT has a breakpoint at 1 nm with a specific surface area about 1431.64 m2/g, which is close to 1445 m2/g determined by the BET approach. It suggests that it is more reasonable to use QSDFT to calculate the PSD of the activated carbon.

²Î¿¼ÎÄÏ×/References:

ÏàËÆÎÄÏ×/References:

[1]¸ß˧,Ö£ÇàéÅ,½â³¿.´óζÈÇø¼äÇâÔÚ»îÐÔÌ¿ÉϵÄÎü¸½Æ½ºâ·ÖÎö[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2012,17(5):368.
¡¡GAO Shuai,ZHENG Qing-rong,XIE Chen.Equilibrium Analysis of Hydrogen Adsorption on Activated Carbon over a Larger Temperature Range[J].Journal of Jimei University,2012,17(5):368.
[2]Îâ´ó¿µ,Íõº£Ãñ,Ö£ÇàéÅ.°±-»îÐÔÌ¿Îü¸½Ê½ÖÆÀäÔÚ´¬²°ÖеÄÓ¦ÓÃ[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2013,18(6):456.
¡¡WU Da-kang,WANG Hai-min,ZHENG Qing-rong.Application of Activated Carbon-ammonia Adsorption Refrigeration System on Ships[J].Journal of Jimei University,2013,18(5):456.
[3]ÍõÏþ»ª,Ö£ÇàéÅ,¸ß˧.¼×ÍéÔÚʯīϩÓë»îÐÔÌ¿ÉϵÄÎü¸½Æ½ºâ[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2013,18(6):451.
¡¡WANG Xiao-huaZHENG Qing-rongGAO Shuai.Adsorption Equilibrium of Methane on Graphene Sheets and Activated Carbon[J].Journal of Jimei University,2013,18(5):451.
[4]ÎâÓÀÉú,Ö£ÇàéÅ.°±ÔÚ»îÐÔÌ¿-ÅòÕÍʯī»ìºÏÎü¸½¼ÁÉϵÄÎü¸½Æ½ºâ·ÖÎö[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2014,19(1):42.
¡¡WU Yong-sheng,ZHENG Qing-rong.Analysis of Adsorption Equilibrium of Ammonia on Composite from Activated Carbon/Expanded Graphite[J].Journal of Jimei University,2014,19(5):42.
[5]Ôø±ó,ÍõÏþ»ª,Öì×ÓÎÄ,µÈ.ÌìÈ»ÆøÎü¸½ÓûîÐÔÌ¿-ÅòÕÍʯī¸´ºÏÎü¸½¼ÁÊÔÖÆ[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2016,21(2):140.
¡¡ZENG Bin,WANG Xiao-hua,ZHU Zi-wen,et al.Preparation of Composite Adsorbent from Activated Carbon and Expanded Graphite for Natural Gas Adsorption£¨ANG£©[J].Journal of Jimei University,2016,21(5):140.
[6]ÌÆÕþ,Ö£ÇàéÅ,ÀîËÉ.´¬²°»ú²Õº¬ÓÍÎÛË®ÓûîÐÔÌ¿ÊÔÖÆ[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2017,22(3):33.
¡¡TANG Zheng,ZHENG Qingrong,LI Song.Preparation of Activated Carbon for Bilge£§s Oily Water[J].Journal of Jimei University,2017,22(5):33.
[7]Î×¾§¾§,ÁÖ½¨Çå,·½ºê´ï,µÈ.»îÐÔÌ¿ºÍʯӢɰÔÚUASBϵͳÖеÄÓ¦ÓÃÑо¿[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2011,16(3):187.
¡¡WU Jing-jing,LIN Jian-qing,FANG Hong-da,et al.The Application of Activated Carbon and Quartz Sand to the UASB[J].Journal of Jimei University,2011,16(5):187.
[8]Áκ£·å,ÑîÇØéÅ,Ö£ÇàéÅ,µÈ.´¬ÓÃÕæ¿Õ¾øÈÈ°å»îÐÔÌ¿/ÅòÕÍʯī¸´ºÏÎüÆø¼ÁÊÔÖÆ[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2018,23(5):367.
¡¡LIAO Haifeng,YANG Qinrong,ZHENG Qingrong,et al.Preparation of a Composite Getter via Activated Carbon and Expanded Graphite for Vacuum Insulation Panels Used on Board Ships[J].Journal of Jimei University,2018,23(5):367.
[9]¸µ¹ðè¤,ÀîÀÚ,ÁÖÖ£ÖÒ,µÈ.»Ç°·¶þ¼×»ùà×षÖ×ÓÓ¡¼£¾ÛºÏÎïµÄÎü¸½ÐÔÄÜ·ÖÎö[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2020,25(3):180.
¡¡FU Guiyu,LI Lei,LIN Zhengzhong,et al.Adsorption Property of a Molecular Imprinted Polymer for Sulfadimidine[J].Journal of Jimei University,2020,25(5):180.
[10]Ö£ÇàéÅ,ÍõÕñÍ¥,²ÌÕñÐÛ,µÈ.»îÐÔÌ¿´¢Çâϵͳ³ä·ÅÆø¹ý³ÌÊÔÑéÑо¿[J].¼¯ÃÀ´óѧѧ±¨(×ÔÈ»¿Æѧ°æ),2011,16(1):50.
¡¡ZHENG Qing-rong,WANG Zhen-ting,CAI Zhen-xiong,et al.Experimental Studies of Hydrogen Storage System on the Activated Carbon During Charge and Discharge Processes[J].Journal of Jimei University,2011,16(5):50.

±¸×¢/Memo

±¸×¢/Memo:

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2022-11-18