Page 34 - 《精细化工》2021年第5期
P. 34

·888·                             精细化工   FINE CHEMICALS                                 第 38 卷

                 Environmental Effects, 2019, 41(20): 2460-2470.     [36]  CHEN N N (陈宁宁), SONG L X (宋立新), ZHENG Y Z (郑云重),
            [25]  GUO Y C  (郭永成). Research progress of viscosity reduction of   et al. Synthetic and properties research of a novel viscosity reducer
                 heavy oil[J]. Contemporary Chemical Industry (当代化工), 2019,   of  oil-soluble polymers[J]. Chemical  Reagents (化学试剂), 2017,
                 48(1): 161-164.                                   39(2): 134-136, 140.
            [26]  MAO J C, LIU J W, PENG Y K, et al. Quadripolymers as viscosity   [37]  SONG L H (宋林花), NI B (倪斌), WU X P (吴信朋). Synthesis of
                 reducers for heavy oil[J]. Energy & Fuels, 2018, 32(1): 119-124.     tetramer MSAZ and application in viscosity reduction for heavy
            [27]  GU X F, LI Y F, YAN J, et al. Synthesis and investigation of a spiro   crude oil with surfactant[J]. Petroleum Processing and Petrochemicals
                 diborate as a clean viscosity-reducer and pour  point  depressor  for   (石油炼制与化工), 2015, 46(6): 79-83.
                 crude oil[J]. Petroleum Chemistry, 2019, 59(6): 570-574.     [38]  ZHANG J (张聚). Development and evaluation of a  heavy oil
            [28]  HUANG T T (黄涛涛). Synthesis and evaluation of  heavy oil   viscosity reducing plugging agent[J]. Yunnan Chemical Technology
                 viscosity reducer based on  N-aryl substituted maleimide[D].   (云南化工), 2018, 45(3): 18.
                 Chengdu: Southwest Petroleum University (西南石油大学), 2015.     [39]  FANG Z H (方振华). Synthesis  and evaluation of a polymer
            [29]  JIANG H J (姜和健). The effect of side chain aromaticity and spacer   viscosity reducer for heavy oil[J]. Chemistry and Adhesion (化学与
                 length in comb-type copolymers on rheological properties of high   粘合), 2015, 37(5): 387-388.
                 wax crude oil[D]. Shanghai: East China University of Science  and   [40]  LIU X C (刘旭超), DU J (杜江),  WANG Q X (王秋霞),  et al.
                 Technology (华东理工大学), 2014.                        Preparation and performance evaluation  of  oil-soluble viscosity
            [30]  GAI D C ( 盖德成 ). Effect of comb-polymers on asphaltene   reducer[J]. Oilfield Chemistry (油田化学), 2018, 35(3): 512-516.
                 aggregation behavior and the rheological property of heavy oil under   [41]  CHEN X  K (陈小凯). Preparation and laboratory evaluation of
                 high pressure[D]. Shanghai: East China University  of  Science and   copolymer of oil-soluble viscosity reducer SA/MMA/VTEO[J].
                 Technology (华东理工大学), 2017.                        Chemical Engineer (化学工程师), 2016, (7): 37-40.
            [31]  SONG H Z (宋红真). Study on synthesis technology and evaluation   [42]  REN H (任昊). Synthesis and evaluation of an oil-soluble viscosity
                 of viscosity reduction copolymer based on long chain   reducer[J]. Guangzhou Chemical Industry (广州化工), 2014, 42(20):
                 methacrylate[D]. Ji'nan: Shandong University (山东大学), 2011.     89-90, 136.
            [32]  LIU J W (刘佳伟), MAO J C (毛金成), ZHOU P Y (周培尧), et al.   [43]  SHI Z Z (石植真). Application  of acrylate graft copolymer in
                 Synthesis and influence factors of an oil-soluble heavy oil viscosity   viscosity reduction of heavy oil[J]. Geological Science  and
                 depressant DMSS terpolymer[J]. Petrochemical Technology (石油化  Technology Information (地质科技情报), 2016, 35(6): 251-256.
                 工), 2017, 46(7): 920-924.                     [44]  LI Y F (李永飞), ZHAO W (赵巍), CHEN G (陈刚), et al. Effects of
            [33]  WANG  Y W (王一雯). Study  on  synthesis and application of   small molecule acetal and ketal compound on crude oil flow and its
                 oil-soluble viscosity reducer[D]. Shenyang: Shenyang University of   mechanism[J].  Complex Hydrocarbon Reservoirs (复杂油气藏),
                 Technology (沈阳工业大学), 2016.                        2015, 8(4): 69-72.
            [34]  QUAN H P, CHEN L, HUANG Z Y, et al. The effect of a kind of   [45]  SHI Z Z (石植真), CHEN Y L  (陈艳玲). Attempt of using
                 hyperbranched polyester with different carbon length on flowability   polyurethane compound as heavy oil  viscosity reducer[J]. Modern
                 for crude oil[J]. Fuel, 2018, 214: 356-362.       Chemical Research (当代化工研究), 2016, (6): 110-113.
            [35]  ZHOU S F (周淑飞), WANG  H G (王洪国), LIAO K  J (廖克俭).   [46]  ZHANG J (张洁), LI X  L (李小龙), CHEN G (陈刚). Small
                 Preparation of broad-spectrun oil-soluble viscosity reducer with   molecular flow improvers for heavy oil and their interaction
                 branches[J]. Petroleum Processing and Petrochemicals (石油炼制与  mechanism[J].  Acta Petrolei  Sinica (Petroleum Processing Section)
                 化工), 2016, 47(11): 82-87.                         (石油学报:  石油加工), 2013, 29(6): 156-161.


            (上接第 873 页)                                        [68]  LI W  Y, WANG B X, ZHANG M H,  et al. All-natural injectable
                                                                   hydrogel with  self-healing and antibacterial properties for wound
            [58]  OHYA  Y, TAKEI T, KOBAYASHI H,  et al. Release behavior of   dressing[J]. Cellulose, 2020, 27(5): 2637-2650.
                 5-fluorouracil from chitosan-gel microspheres immobilizing 5-fluorouracil   [69]  WANG Z K, YANG L, LIU Y L, et al. Ultra-long-term cellular tracing
                 derivative coated with polysaccharides and their cell specific   by a fluorescent AIE bioconjugate with good water solubility over a wide
                 recognition[J]. Journal Microencapsulation, 1993, 10: 1-9.     pH range[J]. Journal of Materials Chemistry B, 2017, 5: 4981-4987.
            [59]  IFTIME M M, MITITELU T L, MARIN L. New formulations based on   [70]   CHEN C Y, CHEN C T. A PNIPAM-based fluorescent nanothermometer
                 salicyl-imine-chitosan hydrogels for prolonged drug release[J]. International   with ratiometric readout[J]. Chemical Communications, 2011, 47: 994-996.
                 Journal of Biological Macromolecules, 2020, 160: 398-408.     [71]  HU H W, JOHN H X, HU H, et al. Glutaraldehyde-chitosan and poly
            [60]  BOONSONGRIT Y, MITREVEJ A, MUELLER B W. Chitosan drug   (vinyl alcohol)  blends, and fluorescence of  their nano-silica composite
                 binding by ionic interaction[J]. European Journal of Pharmaceutics   films[J]. Carbohydrate Polymers, 2013, 91: 305-313.
                 and Biopharmaceutics, 2006, 62: 267-274.      [72]  MAITY S, CHATTERJEE A, CHAKRABORTY N, et al. A dynamic
            [61]  AILINCAI D, MITITELU L  T, MARIN L.  Drug delivery systems   sugar based bio-inspired, self-healing hydrogel exhibiting ESIPT[J].
                 based on biocompatible imino-chitosan hydrogels for local anticancer   New Journal of Chemistry, 2018, 42(8): 5946-5954.
                 therapy[J]. Drug Delivery, 2018, 5(1): 1080-1090.     [73]  BEJAN A, AILINCAI D, SIMIONESCU B C,  et al. Chitosan
            [62]  ZHANG Y L, FU C K, LI Y S, et al. Synthesis of an injectable, self-   hydrogelation with a phenothiazine based aldehyde: A synthetic approach
                 healable and dual responsive hydrogel for drug delivery and 3D cell   toward highly luminescent biomaterials[J]. Polymer Chemistry, 2018,
                 cultivation[J]. Polymer Chemistry, 2017, 8(3): 537-544.     9(18): 2359-2369.
            [63]  BAYAT F, KARIMI A R, ADIMI T. Design of nanostructure chitosan   [74]  HU R (胡蓉), XIN D H (辛德华), QIN A J (秦安军), et al. Polymers
                 hydrogels for carrying zinc phthalocyanine as a photosensitizer and   with aggregation-induced emission characteristics[J]. Acta  Polymerica
                 difloxacin as an antibacterial agent[J]. International Journal of   Sinica (高分子学报), 2018, 62(2): 132-144.
                 Biological Macromolecules, 2020, 159: 598-606.     [75]  GENG Z G, ZHANG H M, XIONG Q Z, et al. A fluorescent chitosan
            [64]  LIU C X (刘长霞), MA C S (马长水), XING Y B (邢宇斌). The new   hydrogel detection platform for the sensitive and selective determination
                 preparation method of chitosan stearate and its structure properties[J].   of trace mercury(Ⅱ) in water[J]. Journal of Materials Chemistry A,
                 Science and Technology of Food Industry (食品工业科技), 2017,   2015, 3(38): 19455-19460.
                 38(8): 276-279.                               [76]  LIU Q Q, LI Q  T, XU S,  et al. Preparation and properties of 3D
            [65]  MARIN L, AILINCAI D, MARES M, et al. Imino-chitosan biopolymeric   printed alginate-chitosan polyion complex hydrogels  for  tissue
                 films. Obtaining, self-assembling, surface and antimicrobial properties[J].   engineering[J]. Polymers, 2018, 10(6): 664.
                 Carbohydrate Polymers, 2015, 117: 762-770.     [77]  SONG J Y, ZHOU H J,  GAO R,  et al. Selective determination of
            [66]  GUO Z Y, REN J M, DONG F, et al. Comparative study of the influence   Cr(Ⅵ) by glutaraldehyde cross-linked chitosan polymer fluorophores[J].
                 of active groups of chitosan derivatives on antifungal activity[J]. Journal   ACS Sensors, 2018, 3(4): 792-798.
                 of Applied Polymer Science, 2013, 127: 2553-2556.     [78]  XU T T, CHU M L, WU Y B, et al. Safer cables based on advanced
            [67]  LAL S, ARORA S, SHARMA C. Synthesis, thermal and antimicrobial   materials with a self-healing technique that can be directly powered
                 studies of some Schiff  bases of chitosan[J]. Journal of Thermal   off and restored easily at any time[J]. New Journal of Chemistry,
                 Analysis and Calorimetry, 2016, 124: 909-916.     2018, 42(7): 4803-4806.
   29   30   31   32   33   34   35   36   37   38   39