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第 5 期杭智军，等: 温度对 N-月桂酰肌氨酸与三乙醇胺反应反应产物结构及性能的影响 ·967·

为 N-月桂酰肌氨酸三乙醇铵盐，高温下（130 ℃）产 Cosmetics (日用化学工业), 2016, 46(1): 53-57.
[11] ZHANG D R, SUN Y G, DENG Q H, et al. Study of the
物主要为 N-月桂酰肌氨酸三乙醇胺酯，反应时间对
environmental responsiveness of amino acid-based surfactant sodium
N-月桂酰肌氨酸与三乙醇胺反应产物结构的影响甚 lauroylglutamate and its foam characteristics[J]. Colloids and
微。 Surfaces A: Physicochemical and Engineering Aspects, 2016, 504:
384-392.
（2）通过对 N-月桂酰肌氨酸与三乙醇胺反应产 [12] People's Republic of China State Administration of Work Safety (中
物的性能研究表明，产物 B 的表面张力随浓度变化国国家安全生产监督管理总局). Emulsifying oil, concentrate fluid
较大，产物 A 的表面张力随浓度变化较小。当质量 and high-water content hydraulic fluid used for powered support: MT
76—2011[S]. Beijing: Standards Press of China (中国标准出版社),
分数小于 0.8%时，产物 B 具有较低的表面张力。 2011: 1-10.
40 ℃下，质量分数为 0.15%时，产物 B 比产物 A 具 [13] LI Y, HU S L, CHENG J H, et al. Acidic ionic liquid-catalyzed
esterification of oleic acid for biodieel synthesis[J]. Chinese Journal
有更好的泡沫稳定性。经过对两种产物的抗硬水性
of Catalysis, 2014, 35(3): 396-406.
能对比发现，产物 B 比产物 A 具有更优异的抗硬水 [14] WANG Y G, WANG P W, YAO C Z, et al. Analysis of
能力，其抗硬水能力提升了 30.5%，更有利于乳液 triethanolamine esters of stearic acid used to synthesize new
softener[J]. Leather and Chemicals (皮革与化工), 2004, 21(6): 29-33.
稳定。 [15] WEN P P, SUN Y Q, SHI X Q, et al. Synthesis of stearic acid
（3）N-月桂酰肌氨酸与三乙醇胺反应产物具有 triethanolamine tri-ester[J]. China Surfactant Detergent＆Cosmetics
优异的乳化及防锈性能，通过研究反应温度对产物 (日用化学工业), 2012, 42(6): 424-427.
[16] SÁNCHEZ C C, PATINO J R. Interfacial, foaming and emulsifying
结构及其泡沫与抗硬水性能的影响，明确其结构与 characteristics of sodium caseinate as influenced by protein
性能的关系，指导开发性能更加稳定、绿色的浓缩 concentration in solution[J]. Food Hydrocolloids, 2005, 19(3):
407-416.
液产品，以期满足不同矿区水质对浓缩液性能的要
[17] LIU H S (刘宏生), WANG J Q (王景芹). Foam properties of sodium
求。 α-olefin sulfonate compounded systems[J]. Journal of Qingdao
University of Science and Technology (Natural Science Edition) (青
参考文献：岛科技大学学报: 自然科学版), 2013, 34(1): 12-16.
[18] YANG Y (杨奕), TANG S F (唐善法), WU H (吴浩), et al.
[1] LIU R F (刘汝锋), CHEN Y X (陈亿新), SHANG X Q (尚小琴), et
al. Preparation of microemulsion grinding fluid and its antirust Performance evaluation of low interfacial tension temperature and
performance[J]. Chemical Industry and Engineering Progress (化工 salt resistant YUDP foaming agent[J]. Fine Chemicals (精细化工),
进展), 2012, 31(8): 1857-1860. 2019, 36(8): 1689-1694.
[2] CAI M J, LI Q Q, CHEN X M. Synthesis, surface activity, and [19] Standardization Administration of the People's Republic of China (中
antifogging property of triethanolamine monoiaurate ester[J]. 国国家标准化管理委员会). Surface active agents-Determination of
Chinese Journal of Chemical Physics, 2015, 31(2): 223-229. stability in hard water: GB 7381—2010[S]. Beijing: Standards Press
of China (中国标准出版社), 2010: 1-4.
[3] CHEN L (陈丽), ZHOU M H (周美华). Research trend of amino
[20] SUN G N (孙冠男), ZHENG L Q (郑利强), SUN J C (孙继超).
acid-based surfactants[J]. Fine and Specialty Chemicals (精细与专用
化学品), 2004, 12(19): 7-11. Self-assembly of surfactants controlled by weak interactions（Ⅱ）the
[4] GENG E H (耿二欢), HONG Y Q (洪玉倩), WANG W D (王文德). structure and design of surfactants[J]. China Surfactant Detergent &
Study on surfactant blending performance of sodium N-lauroylalanine[J]. Cosmetics (日用化学工业), 2019, 49(2): 13-18.
China Surfactant Detergent & Cosmetics (日用化学工业), 2017, [21] HANG Z J (杭智军), WANG Y C (王玉超), BAI F F (白飞飞), et al.
47(12): 681-684. Discussion on performance requirements and application of defoamer
[5] TIAN H J (田会娟), LIU X H (柳鑫华), RUI Y L (芮玉兰). Progress for hydraulic support concentrated liquid[J]. Coal and Chemical
in research on amino acids as corrosion inhibitors in acid Industry (煤炭与化工), 2018, 41(12): 87-89.
solutions[J]. Corrosion & Protection (腐蚀与防护), 2009, 30(3): [22] ZHU T Y (朱天一), LI M (李茂), CHENG L (程亮), et al. Types and
186-189. characteristics introduction of antifoaming agent[J]. Lubricating Oil
[6] GUO X H (郭学辉), WANG K (王康), HU B S (胡百顺), et al. (润滑油), 2017, 32(6): 23-25.
Research progress on corrosion inhibition mechanism of amino acid [23] BAEZA R, SANCHEZ C C, PILOSOF A R, et al. Interfacial and
corrosion inhibitors[J]. Corrosion Science and Protection Technology foaming properties of prolylenglycol alginates: Effect of degree of
(腐蚀科学与防护技术), 2013, 25(1): 63-66. esterification and molecular weight[J]. Colloids & Surfaces B
[7] LI S F (黎四芳), LI H (李红). Corrosion inhibition performances of Biointerfaces, 2004, 36(3): 139-145.
sodium N-lauroyl sarcosinate and its composites[J]. Corrosion [24] ZHAO X (赵晓), HU X Y (胡学一), FANG Y (方云), et al. Unique
Science and Protection Technology (腐蚀科学与防护技术), 2008, physicochemical properties of sodium 9, 10, 12, 13-tetrahydroxyl stearate
20(4): 289-291. in cold hard water and under neutral pH condition[J]. Fine Chemicals
[8] HONG Y Q (洪玉倩), SHI L W (史立文), GENG E H (耿二欢), et (精细化工), 2013, 30(9): 1003-1007.
al. Study on the surface performance of sodium N-lauroylamino acid[J]. [25] LIU H Q (刘红芹), SHI G Y (石国英), ZHANG X X (张晓旭), et al.
China Cleaning Industry (中国洗涤用品工业), 2019, (2): 17-21. Synthesis and properties of lauryl polyoxyethylene(5) amine
[9] WANG K (王宽), SUN J L (孙吉龙), LI Z Y (李泽勇). Study on the oxide[J]. Fine Chemicals (精细化工), 2017, 34(8): 849-853.
self-thickening system of sodium lauroyl sarcosinate[J]. China [26] ZHAO T T(赵涛涛), GONG H J (宫厚健), XU G Y(徐桂英), et
Surfactant Detergent & Cosmetics (日用化学工业), 2018, 48(12): al.Investigation of salts tolerance of anionic surfactants in aqueous
22-25. solutions[J].Oilfield Chemistry(油田化学), 2010, 27(1):112-118.
[10] YU F (俞芳). Current situation with respect to synthesis technology [27] CHEN Y J( 陈贻建). The Ca 2+ -tolerant mechanism of anionic-
of sodium N-acyl sarcosinate[J]. China Surfactant Detergent & nonionic surfactant[D]. Jinan: Shandong University(山东大学), 2014.

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