·632·                             精细化工   FINE CHEMICALS                                  第 36 卷

            平均粒径为 59.40 nm，PDI 为 0.493，表明粒子分布                  [6]   Sun Xiaoxiao (孙潇潇), Xie Yongxin (谢永新), Chen Zhaoyang (陈
                                                                   朝阳), et al. Advance in the research of modification of waterborne
            均匀；漆膜的吸水率为 11.3%；接触角为 97.0，表
                                                                   alkyd resin[J]. Paint  Coatings Industry (涂料工业), 2012, 42(10):
            明漆膜的耐水性较好；此外，热重分析表明，经过                                 77-80.
                                                               [7]   Lai Shuili (来水利), Yu Jinfeng (于金凤), Wang Jingli    (王晶丽), et
            环氧改性，树脂的热稳定性也得到较大的提高。
                                                                   al. Preparation and application of epoxy-modified waterborne alkyd
                （3）为进一步改善漆膜的耐水性及热稳定性，                              amino-baking  coatings[J].  Paint    Coatings  Industry  (涂料工业),
            可继续探讨油酸种类和环氧树脂种类对性能的影响。                                2016, 46(1): 27-31.
                                                               [8]   Chen Shijie ( 陈士 杰 ).  Coating  process  (Part  1)[M].  Beijing:
                                                                   Chemical Industry Press, 1994: 291-300.
            参考文献：
                                                               [9]   Ti Tianbao, Liang Liang, Qi Zengqing, et al. Study on synthesis of
            [1]   Haase  M  F,  Grigoriev  D  O,  Möhwald  H,  et al.  Development  of   waterborne styrene-modified alkyd resin[J]. Paint  Coatings Industry,
                 nanoparticle stabilized polymer nanocontainers with high content of   2011, 41(7): 28-32.
                 the  encapsulated  active  agent  and  their  application  in  water-borne   [10]  Hu Qiaosheng (胡乔生), Ye Jiabo (叶家波), Fan Xiaolin (范小林), et
                 anticorrosive  coatings[J].  Advanced  Materials,  2012,  24(18):  2429-   al.  Development  of  water  soluble  alkyds  coatings[J].  Journal  of
                 2435.                                             Gannan Teachers College (赣南师范大学学报), 2005, 26(6): 54-57.
            [2]   Pathan S,Ahmad S.Synergistic effects of linseed oil based waterborne   [11]  Dutta N, Karak N, Dolui S K. Alkyd–epoxy blends as multipurpose
                 alkyd  and  3-isocynatopropyl  triethoxysilane,  highly  transparent,   coatings[J]. Journal of Applied Polymer Science, 2010, 100(1): 516-521.
                 mechanically  robust,  thermally  stable,  hydrophobic,  anticorrosive   [12]  Hasmukh S, Bhavdeep K, Ketan B, et al. Surface coating studies of
                 coatings[J].  ACS  Sustainable  Chemistry    Engineering,  2016,  4(6):   od  alkyd-castor  oil-expoxy  resin  condensate-ketone  resin  blend[J].
                 3062-3075.                                        International of Polymeric Materials, 2010, 59(1): 25-32.
            [3]   Chen Weidong (陈卫东), Zhang Pengyun (张鹏云), Chen Yanli (陈  [13]  Qi Zengqing (齐增清), Liang liang (梁亮), Yi Tianbao (弋天宝), et
                 艳丽),  et al.  Domestic  research  progress  in  modification  of  alkyd   al. Synthesis and application research of epoxy modified water-borne
                 resin[J]. Thermosetting Resin (热固性树脂), 2014, 29(6): 56-59.   alkyd resins[J]. New building materials (新型建筑材料), 2011, (7):
            [4]   Zhang Y X, Li S M, Liu J H, et al. Research of erosion of alkyd resin   61-65.
                 coating and effect of chlorothalonil on the mouldpro of properties[J].   [14]  Yuan Teng (袁腾), Liu wenji (刘文济), Zhao Tao (赵韬), et al. The
                 Journal of Functional Materials, 2013, 44(10): 1375-1380.   impact  of  expoxy  acrylate-modified  on  the  properties  waterboenr
            [5]   Zhou X H, Yuan T, Zhao T, et al. Study on the synthesis of air dry   alkyd  resin[J].  Journal  of  functional  materials  (功能材料),  2015,
                 water-based alkyd resin[J]. Thermosetting Resin, 2014, 29(4): 1-7.   2(46): 2028-2032.


            （上接第 626 页）                                            superhydrophobic  Fe 3O 4/PU  sponge  for  oil-water  separation[J].
                                                                   Applied Surface Science, 2018, 427: 56-64.
                （2）本研究制备的超疏水海绵具有优异的油/                          [7]   Rezayi  T,  Entezari  M.  Wettability  properties  vary  with  different
            水混合物的分离能力，且具有磁响应特性，因此可                                 morphologies of ZnO nanoparticles deposited on glass and modified
                                                                   by stearic acid[J]. New Journal of Chemistry, 2016, 40(3): 2582-2591.
            以与外部磁场耦合，以实现油/水混合物的磁驱动选                            [8]   Sukamanchi R, Mathew D, Santhosh-Kumar K. Durable superhydrophobic
            择性分离。此外，还可以通过简单的挤压方式实现                                 particles mimicking leafhopper surface: superoleophilicity and very
                                                                   low surface energy[J]. Acs Sustainable Chemistry, 2016, 5(1): 252-260.
            油品的回收和材料的循环使用，经过 5 次油/水循环                          [9]   Liu  Y, Ma  J, Wu  T,  et al.  Cost-effective  reduced  graphene  oxide-
            分离实验后，油品的分离效率没有明显下降。因此，                                coated  polyurethane  sponge  as  a  highly  efficient  and  reusable  oil-
                                                                   absorbent[J].  Acs  Applied  Materials  &  Interfaces,  2013,  5(20):  10018-
            在油水分离过程中，深入地研究油-水-固-气之间的
                                                                   10026.
            界面相互作用，以提供理论指导，在处理含油工业                             [10]  Khanoonkon N, Yoksan R, Ogale A. Morphological characteristics of
            废水和海洋溢油方面具有很大的应用潜力。                                    stearic  acid-grafted  starch  compatibilized  linear  low  density
                                                                   polyethylene/thermoplastic starch blown film[J]. European Polymer
                                                                   Journal , 2016, 76: 266-277.
            参考文献：                                              [11]  Wang  J,  Zheng  Y.  Oil/water  mixtures  and  emulsions  separation  of
            [1]   Wang  B,  Liang  W,  Guo  Z,  et al.  Biomimetic  superlyophobic  and   stearic  acidfunctionalized  sponge  fabricated  via  a  facile  one-step
                 superlyophilic materials applied for oil/water separation: a new strategy   coating  method  [J].  Separation  &  Purification  Technology,  2017,
                 beyond nature[J]. Chemical Society Reviews, 2015, 44(1): 336-361.   181: 183-191.
            [2]   Peng  H,  Wang  H,  Wu  J,  et al.  Preparation  of  superhydrophobic   [12]  Zhang  X,  Liu  D,  Ma  Y,  et al.  Super-hydrophobic  graphene  coated
                 magnetic cellulose sponge for removing oil from water[J]. Industrial   polyurethane(GN@PU)  sponge  with  great  oil-water  separation
                 & Engineering Chemistry Research, 2016, 55(3): 832-838.   performance[J]. Applied Surface Science, 2017, 422: 116-124.
            [3]   Wang J, Wang H, Geng G. Highly efficient oil-in-water emulsion and   [13]  Lu Y,  Wang Y,  Liu  L, et al.  Environmental-friendly  and  magnetic/
                 oil layer/water mixture separation based on durably superhydrophobic   silanized ethyl cellulosesponges as effective and recyclable oil-absorption
                 sponge  prepared  via  a  facile  route[J].  Marine  Pollution  Bulletin,   materials[J]. Carbohydrate Polymers, 2017, 173: 422-430.
                 2018, 127: 108-116.                           [14]  Xiang  Y,  Pang  Y,  Jiang  X,  et al.  One-step  fabrication  of  novel
            [4]   Beshkar  F,  Khojasteh H ,Salavati-Niasari M.  Recyclable  magnetic   superhydrophobic  and  superoleophilic  sponge  with  outstanding
                 superhydrophobic  straw  soot  sponge  for  highly  efficient  oil/water   absorbency  and  flame-retardancy  for  the  selective  removal  of  oily
                 separation[J]. Journal of Colloid & Interface Science, 2017, 497: 57-65.   organic solvent from water[J]. Applied Surface Science, 2018, 428:
            [5]   Liu  L,  Lei  J,  Li  L,  et al.  A  facile  method  to  fabricate  the   338-347.
                 superhydrophobic  magnetic  sponge  for  oil-water  separation[J].   [15]  Yang W, Gao H, Zhao Y, et al. Facile preparation of nitrogen-doped
                 Materials Letters, 2017, 195: 66-70.              graphene  sponge  as  a  highly  efficient  oil  absorption  material[J].
            [6]   Li  Z,  Lin  B,  Jiang  L,  et al.  Effective  preparation  of  magnetic     Materials Letters, 2016, 178: 95-99.