淡水钻井液用缓蚀剂的研究
|
摘要
在钻井过程中,钻具的腐蚀相当严重,并且随着钻井方向向纵深发展,温度、压力、井层地质结构的变化等各种因素使得钻具的腐蚀破坏日趋严重。江苏油田承钻油井过程中发现钻具腐蚀严重,前人通过对钻具在钻井液中的腐蚀产物进行EDS分析,发现腐蚀产物主要成分是Fe2O3,从而推断出钻井液对钻具的腐蚀主要是氧的去极化所致。本文主要是研究钻具在钻井液中遭受腐蚀的影响因素,并筛选出适用的缓蚀剂,通过复配改进缓蚀剂的缓蚀效率,减缓腐蚀速率。
通过阴、阳极极化曲线探讨了钻具在腐蚀过程中的一些影响因素。研究发现,随着钻井液pH值的增大,钻具钢的腐蚀速率减小。随着温度的升高,阳极区的致钝电流明显增大,说明温度升高,钝化膜形成的难度增加。另外,腐蚀速度随盐含量的增加先变大后减小,可能是当盐含量增到一定程度后阻滞了介质中的溶解氧向金属表面扩散,故降低了腐蚀速度。泥浆中各离子对腐蚀速率影响顺序为:Cl->S2->HCO3-> SO42-,Cl-对腐蚀的影响最大,滞后环实验亦证明了Cl-含量的增加,局部腐蚀的敏感性增加,且保护电位有所降低,耐蚀性降低。
从旋转动态模拟挂片实验中发现,随着转速的增加,腐蚀速率逐渐增加;随着腐蚀时间和通气量的增加,腐蚀速率先增大后减小;随着温度的增加,腐蚀速率也增大,且从腐蚀速率的大小可以看出,各因素的影响顺序:温度﹥转速﹥腐蚀时间﹥通气量。
通过线性极化法筛选出单组分缓蚀效果较好的钼酸钠、硅酸钠、高锰酸钾、月桂酰肌氨酸钠以及有机胺D为复配的基本配方。利用极化曲线法评定复合缓蚀剂的缓蚀效果,并研究其缓蚀机理。研究表明,复配后的缓蚀效果比未添加缓蚀剂或添加单组分缓蚀剂时要强,说明复合缓蚀剂各组分之间具有一定的协同缓蚀效果,能够有效地在金属表面形成具有互补性的保护膜,能有效提高自腐蚀电位,降低腐蚀电流。
通过线性极化法进一步验证各复合缓蚀剂的缓蚀效率,并用交流阻抗法对缓蚀率大于90%的配方进行研究。结果表明,复合缓蚀剂能够在金属表面形成屏蔽性能良好的比较完整的保护膜,有效地阻止腐蚀介质向金属表面扩散和降低电荷传递的流量,
The corrosion of drill tools is a serious problem in the drilling engineering. It will become even worse when the drill tools have gone deeper and the surroundings have changed, such as temperature, pressure and geologic structure and so on. Drill tools have corroded seriously when they are used in the engineering of oil exploitation by Jiangsu Oil Field. It is concluded by EDS(Energy Dispersive Spectroscopy) analysis on corrosion products of drill tools in drilling fluid that the main component of the corrosion products on local drill tools is Fe2O3. Thus the corrosion of drill tools is mainly caused by the depolarization of dissolved oxygen. Factors on corrosion were studied. Inhibitors that could be used in the practice were selected. Efficiencies of composite inhibitors were improved.
Results tested by polarization curves showed that the corrosion rate decreased with the increasing of pH value. The passive current in the anodic area had obviously increased with the increasing of temperature. This proved that it would be more difficultly for the passive film to form with the increasing of temperature. In addition, the corrosion rate increased firstly and then decreased with the increasing of the salt content. The high salt content could hinder oxygen from arriving the metal surface and therefore, there was a decrease in the corrosion rate. It could be inferred from the results the sequence of the effect on corrosion rate is Cl->S2->HCO3->SO42-. The influence of Cl- on the corrosion is the greatest. Results tested by potentiadynamic polarization curves proved that the sensitivity of corrosion partly increased with the increasing of Cl- content. The protective potential and corrosion resistance decreased.
Results from the weight loss test showed that the corrosion rate increased with the increasing of the agitating speed, temperature. The corrosion rate increased firstly and then decreased with the increasing of corrosion time and quantity of oxygen. The results indicated the sequence of the effect on corrosion rate is temperature> agitating speed>time> quantity of oxygen.
Sodium molybdate, sodium silicate, potassium permanganate, sodium
通过阴、阳极极化曲线探讨了钻具在腐蚀过程中的一些影响因素。研究发现,随着钻井液pH值的增大,钻具钢的腐蚀速率减小。随着温度的升高,阳极区的致钝电流明显增大,说明温度升高,钝化膜形成的难度增加。另外,腐蚀速度随盐含量的增加先变大后减小,可能是当盐含量增到一定程度后阻滞了介质中的溶解氧向金属表面扩散,故降低了腐蚀速度。泥浆中各离子对腐蚀速率影响顺序为:Cl->S2->HCO3-> SO42-,Cl-对腐蚀的影响最大,滞后环实验亦证明了Cl-含量的增加,局部腐蚀的敏感性增加,且保护电位有所降低,耐蚀性降低。
从旋转动态模拟挂片实验中发现,随着转速的增加,腐蚀速率逐渐增加;随着腐蚀时间和通气量的增加,腐蚀速率先增大后减小;随着温度的增加,腐蚀速率也增大,且从腐蚀速率的大小可以看出,各因素的影响顺序:温度﹥转速﹥腐蚀时间﹥通气量。
通过线性极化法筛选出单组分缓蚀效果较好的钼酸钠、硅酸钠、高锰酸钾、月桂酰肌氨酸钠以及有机胺D为复配的基本配方。利用极化曲线法评定复合缓蚀剂的缓蚀效果,并研究其缓蚀机理。研究表明,复配后的缓蚀效果比未添加缓蚀剂或添加单组分缓蚀剂时要强,说明复合缓蚀剂各组分之间具有一定的协同缓蚀效果,能够有效地在金属表面形成具有互补性的保护膜,能有效提高自腐蚀电位,降低腐蚀电流。
通过线性极化法进一步验证各复合缓蚀剂的缓蚀效率,并用交流阻抗法对缓蚀率大于90%的配方进行研究。结果表明,复合缓蚀剂能够在金属表面形成屏蔽性能良好的比较完整的保护膜,有效地阻止腐蚀介质向金属表面扩散和降低电荷传递的流量,
The corrosion of drill tools is a serious problem in the drilling engineering. It will become even worse when the drill tools have gone deeper and the surroundings have changed, such as temperature, pressure and geologic structure and so on. Drill tools have corroded seriously when they are used in the engineering of oil exploitation by Jiangsu Oil Field. It is concluded by EDS(Energy Dispersive Spectroscopy) analysis on corrosion products of drill tools in drilling fluid that the main component of the corrosion products on local drill tools is Fe2O3. Thus the corrosion of drill tools is mainly caused by the depolarization of dissolved oxygen. Factors on corrosion were studied. Inhibitors that could be used in the practice were selected. Efficiencies of composite inhibitors were improved.
Results tested by polarization curves showed that the corrosion rate decreased with the increasing of pH value. The passive current in the anodic area had obviously increased with the increasing of temperature. This proved that it would be more difficultly for the passive film to form with the increasing of temperature. In addition, the corrosion rate increased firstly and then decreased with the increasing of the salt content. The high salt content could hinder oxygen from arriving the metal surface and therefore, there was a decrease in the corrosion rate. It could be inferred from the results the sequence of the effect on corrosion rate is Cl->S2->HCO3->SO42-. The influence of Cl- on the corrosion is the greatest. Results tested by potentiadynamic polarization curves proved that the sensitivity of corrosion partly increased with the increasing of Cl- content. The protective potential and corrosion resistance decreased.
Results from the weight loss test showed that the corrosion rate increased with the increasing of the agitating speed, temperature. The corrosion rate increased firstly and then decreased with the increasing of corrosion time and quantity of oxygen. The results indicated the sequence of the effect on corrosion rate is temperature> agitating speed>time> quantity of oxygen.
Sodium molybdate, sodium silicate, potassium permanganate, sodium
引文
[1] 黄国柱译. 日本腐蚀损失调查报告. [J].腐蚀科学与防护技术,1979,(3):32~39.
[2] 石声泰,徐克薰,顾皇之. 金属腐蚀和防护的研究发展概况. [J].腐蚀与防护,1980,(1):2~9.
[3] 张兴儒. 油田腐蚀状况与腐蚀控制. [J].腐蚀科学与防护技术,1989,1(2):1~5.
[4] 沈长寿. 钻井液中抗氧缓蚀剂的研究. [J].石油与天然气化工,2000,29(3):139~140.
[5] 傅朝阳,郑家燊,姚安林等. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5):257~263.
[6] 陈理中等译. 美国钻井手册[M]. 北京:石油工业出版社. 1980.
[7] 傅朝阳,郑家燊,姚安林等. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5):257~263.
[8] 候彬,周永璋,魏无际. 钻具的腐蚀与防护. [J].钻井液与完井液,2003,2(2):48~53.
[9] 黄李荣. 钻柱在存放过程中的腐蚀及防腐问题. [J].钻采工艺,2003,26(5):86~87.
[10] Hendrickson J R. Fatigue Studies of Drill Pipe Immersed in Drilling Mud with H2S and CO2 [J]. Final Report, 1984: 88.
[11] 房志忠,彭芳明,刘烈炜等. 钻杆 40Cr 钢在含 H2S 钻井液中的腐蚀疲劳. [J].华中理工大学学报,1995,23(11):148~153.
[12] 吴修斌,李铭瑞,罗富先. 复合缓蚀剂 ZH-1 在中原油田聚合物盐水泥浆中的应用. [J].油田化学,1996,13(2):100~105.
[13] 彭芳明,吕战鹏,吴修兵等. 聚合物盐水泥浆缓蚀剂研究. [J].油田化学,1996,13(2):106~110.
[14] 单江涛,周永璋,魏无际等. G~105 钢在盐水钻井液中的腐蚀行为. [J].材料保护,2004,37(6):44~46.
[15] 华明琪,贺承祖. 钻具的腐蚀与防护. [J].油田化学,1988,5(1):71.
[16] Donbarn J E. Drilling Fluids [J]. Corrosion,1984: 176.
[17] Postagta J R. The sulfate reducing bacteria [M]. Cambridge, University Press, Cambridge, England,1984.
[18] Cormbie D.J,Thomas J D R. Corrosion of iron by sulfate-reducing bacteria [J]. Chemical and Industry. 1980,21(6): 30.
[19] 万里平,孟英峰,梁发书等. 欠平衡钻井中钻具的腐蚀与磨蚀. [J].西部探矿工程,2004,95(4):62~65.
[20] 张天胜. 缓蚀剂[M]. 北京:化学工业出版社,2002: 391~411.
[21] 郑家燊,黄魁元. 缓蚀剂科技发展历程的回顾与展望. [J].材料保护,2000,33(5):11~15.
[22] Walker R. BTA as a Corrosion inhibitor for immersed Cu [J]. Corrosion, 1973,29(7):290.
[23] Salch R M. Corrosion inhibition by naturally occurring substances VⅡ, the effect of aqueous extracts of some leaves & fruit-peels on the Corrosion of steel, Al, Zn and Cu in acid [J]. British Corrosion J, 1982,17(3) :131.
[24] Fouda A S. The role of some thiosemicarbazide derivatives in the corrosion inhibition of Al in HCl [J]. Corrosion Science, 1988, 26(9):719.
[25] 荒牧国次. 缓蚀剂研究 40 年. [J].材料环境,1993,42(5):305.
[26] Vukasovich M S. Application for the versatile molybdate inhibitor [J]. Corrosion Science,1989,29(8):15~17.
[27] Kalman D G. Sodium molybdate as a corrosion inhibitor of mild steel in natural waters [J]. Corrosion,1993,49(8):21~25.
[28] Devasenapath A. Effect of externally added molybdate on repassivation & stress corrosion cracking of type 304 stainless steel in HCl [J]. Corrosion,1996,52(4):243.
[29] Mustafa C M. Corrosion inhibition of Al by molybdate citric acid & nitrite in simulated cooling water [J]. Corrosion Prevention & Control,1997,44(2):49.
[30] 黄魁元,曾兆民. 我国缓蚀剂科学技术十年进展[A]. 中国腐蚀与防护学会成立十周年学术论文集[C]. 北京:中国腐蚀与防护学会,1990.
[31] 郑家燊,齐公台. 我国缓蚀剂研究和应用进展[A]. 第十届全国缓蚀剂学术讨论会论文集[C]. 海口:缓蚀剂专业委员会,1997.
[32] 郑家燊. 水溶性、油溶性和气相缓蚀剂研究与应用情况[J]. 腐蚀与防护,1997,18(5):36.
[33] 陶映初. 一种新型钢材酸浸缓蚀剂(LK-45 植酸提取液)锅炉之酸洗除垢. [J].材料保护,1987,28(4):19~22.
[34] 郭稚弧. 几种植物萃取液对碳钢腐蚀的抑制作用. [J].材料保护,1989,30(2):9~12.
[35] 莫自如,辛剑,汤克峻等. MBT、HEDP、Zn2+与钼酸盐协同缓蚀效应的研究. [J].腐蚀科学与防护技术,1992,4(4):301~320.
[36] 陆柱. 第五届亚太腐蚀控制会议及第廿七届澳洲腐蚀协会年会简介. [J].腐蚀与防护,1988,(3):48~50.
[37] 沈长寿, 熊楚才,黄红兵. 钻具抗氧缓蚀剂的研究. [J].钻井液与完井液,1994,11(4):3~8.
[38] 杨振杰. IADC 钻井液处理剂分类. [J].钻井液与完井液,1997,14(1): 32.
[39] K D Demadis, A Stathoulopoulou. Multifunctional, Environmentally Friendly Additives for Control of Inorganic Foulants in Industrial Water and Process Applications [J]. Materials Performance, 2006,45: 40~44.
[40] Kasper K Ostergaard, Rahim Masoudi, Bahman Tohidi. A general correlation for predicting the suppression of hydrate dissociation temperature in the presence of thermodynamic inhibitors [J]. Journal of Petroleum Science & Engineering,2005,48(1): 70~80.
[41] 缪明富,郭建平,马卫. 90 年代钻井液处理剂发展趋势. [J].钻采工艺,1999,22(4): 57~61.
[42] Y.Tomoe. Unusual corrosion of a drill pipe in newly developed drilling mud during deep drilling [J]. Corrosion, 1999, 55(7) : 706~713.
[43] Bellos, Thomas J. Corrosion inhibitor for highly oxygenated systems[P]. US 4311662, 1982-01-19.
[44] James E.Donham. Chemical control of drilling corrosion [J]. Materials Performance, 1976, 15(10) : 34~38.
[45] M.A.Al-Marhoun. Treatment of drilling fluid to combat drill pipe corrosion [J]. Corrosion, 1990, 46(9) : 778~782.
[46] G.T.Hefter. Organic corrosion inhibitors in neutral solutions; Part 1-Inhibition of steel, copper, and aluminum by straight chain carboxylates [J]. Corrosion, 1997, 53(3) : 657~666.
[47] Dadgar,Ahmad. Corrosion inhibitors for clear, calcium-free high density fluids [P]. US4784779, 1988-11-15.
[48] 赵福祥,范荣增,范旭波等. DPI-03 型钻井液缓蚀剂的研制. [J].油田化学,1996,13(1):37~39.
[49] 刘兴重. 油田高温缓蚀剂 N-(9-菲甲基)喹啉氯化物的合成及复配液缓蚀性能的初步研究. [J].武汉冶金科技大学学报,1996,19(2):165~167.
[50] 徐智谋,郑家燊,董泽华等. 废弃钻井液处理中脱稳药剂对设备腐蚀的影响和控制. [J].材料保护,1999,32(8):29~32.
[51] 唐善法,付绍斌,童伏松等. 复合盐防腐钻井液的研制与现场应用. [J].石油钻采工艺,1998,20(4):41~45.
[52] 唐善法,付绍斌,童伏松等. 复合盐防腐钻井液缓蚀剂 DFP 的研制与应用. [J].油田化学,1997,14(2):110~114.
[53] 唐善法,付绍斌,童伏松等. 复合盐钻井液对钻具的腐蚀机理研究. [J].武汉工业大学学报,1997,19(3):79~82.
[54] 方慧,潘小镛. 缓蚀剂 PF-Ⅰ在加重盐水钻井液中的应用. [J].钻井液与完井液,1997,14(3):36~37.
[55] 黄志宇,何雁,冯英等. 泥浆缓蚀剂 HZ-1 的研究. [J].西安石油学院学报,2001,16(5):54~57.
[56] 沈长寿. 钻井液中抗氧缓蚀剂的研究. [J].石油与天然气化工,2000,29(3):139~140.
[57] 万里平,孟英峰,梁发书. 甲酸盐钻井液对 N80 钢的腐蚀研究. [J].钻采工艺,2003,26(6):83~88.
[58] 郑叔杰,许京国,苏秀纯等. 千米桥潜山小间隙欠平衡钻井液研究. [J].石油钻采工艺,2002,24(1):33~36.
[59] 宋学锋,黄琳,周永璋等. 盐水钻井液中钼酸盐系缓蚀剂对钻杆缓蚀的影响. [J].材料保护,2006,(2):59~62.
[60] 张天胜. 缓蚀剂[M]. 北京:化学工业出版社,2002: 5~10.
[61] 李荻. 电化学原理[M]. 北京:北京航空航天大学出版社,2002: 401~417.
[62] 魏宝明. 金属腐蚀理论及应用[M]. 北京:化学工业出版社,2001: 2~10.
[63] 陈国华,王光信. 电化学方法应用[M]. 北京:化学工业出版社,2003.
[64] 王佳,曹楚南,陈家坚. 缓蚀剂理论与研究方法的进展. [J].腐蚀科学与防护技术,1992,4(2):79~86.
[65] 宋诗哲. 腐蚀电化学研究实验方法[M]. 北京:化工出版社,1988.
[66] 张昭,张鉴清,王建明等. 硫酸钠溶液中 2024-T3 铝合金孔蚀过程的电化学噪声特征. [J].中国有色金属学报,2001,11(2):284~287.
[67] 宣爱国. 电化学噪声测试技术. [J].武汉化工学院学报,2003,25(2):20~22.
[68] 陈旭俊,王海林. 孔蚀缓蚀剂及其理论研究评述(二). [J]. 材料保护,1991,24(8) :4~7.
[69] 王红艳. AES 和 XPS 研究 Cu-Sn-P 镀层表面 PMTA 复合膜. [J].光谱实验室,1999,16(5):480~484.
[70] 严川伟等. 2-巯基苯并恶唑(MBO)在铜表面缓蚀膜研究. [J].中国腐蚀与防护学报,1999,19(6):367~371.
[71] 何新快. 缓蚀剂的研究现状及展望. [J].材料保护,2003,36(8):1~3.
[1] 侯彬. 饱和盐水钻井液缓蚀剂的研究[D]. 南京:南京工业大学,2003.
[2] 魏宝明. 金属腐蚀理论及应用[M]. 北京:化学工业出版社,1984: 115~124.
[3] 李荻. 电化学原理[M]. 北京:北京航空航天大学出版社,1998: 193~211.
[4] 傅朝阳,郑家燊,姚安林. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5) :257~263.
[5] 任文超. 不同晶须分数 Al18B4O33w/Al 复合材料的腐蚀敏感性. [J].应用科技,2004,31(7):10~12.
[6] 刘幼平,夏念勇,赵旭晖. 孔蚀保护电位剖析. [J].中国腐蚀与防护学报,1997,17(4):241~247.
[7] 梁成浩,牟战旗. 模拟体液中 316L 不锈钢和 Co-Cr 合金生物材料腐蚀行为研究. [J].中国生物医学工程学报,2000,19(4):432~435.
[8] 刘继华,李荻,朱国伟等. 7075 铝合金应力腐蚀敏感性的 SSRT 和电化学测试研究. [J].腐蚀与防护,2005,26(1):6~9.
[9] 许淳淳,刘幼平,张晓波等. 孔蚀阴极保护电位测试方法的研究. [J].电化学,1999,5(2):152~156.
[1] 曹楚南. 电化学原理[M]. 北京:化学工业出版社,2004: 117~150.
[2] 柳鑫华,梁英华,芮玉兰. 海水循环冷却水系统钼酸盐及钨酸盐缓蚀剂的研究现状及展望. [J].清洗世界,2006,22(1):20~24.
[3] 苏连芳,金振兴. ATMP、硫脲缓蚀性能研究. [J].锦州师范学院学报(自然科学版),2001,22(2):29~31.
[4] 骆素珍,郑玉贵,敬和民等. NaNO2 对 20SiMn 低合金钢在 3%NaCl 溶液中空蚀损伤的缓蚀作用. [J].腐蚀科学与防护技术,2004,16(6):347~351.
[5] 徐群杰,马姗姗,陈震芳. 钨酸盐及其复配对模拟水中碳钢的缓蚀作用研究. [J].上海电力学院学报,2005,21(3):268~270.
[6] 马欣. 金属在含氯离子水介质中的腐蚀行为. [J].石油化工腐蚀与防护,2005,22(5):5~9.
[7] 许淳淳,何海平. 钨酸钠与十二烷基苯磺酸钠协同缓蚀作用研究. [J].表面技术,2005,34(3):33~35.
[8] 王慧龙,姜文凤,郑家燊. 巯基三唑化合物与有机季铵盐的缓蚀协同效应. [J].材料保护,2006,39(1):9~11.
[9] 张丽华. 用线性极化法研究金属材料在天然碱苛化体系中的腐蚀行为. [J].内蒙古石油化工,2002,(27):42~47.
[10] N.Bui,A.Irhzo,F.Oabosi and Y.Limouzin-Maire. On the Mechanism for Improved Passivation by Additions of Tungsten to Austenitic Stainless Steels [J]. Corrosion,1983,39(12): 491~496.
[11] 杨文庆. 钼酸钠系缓蚀剂的进展. [J].材料保护,1996,28(8): 16~18.
[12] Patnaik, S.R. Vdayabhanu,G.Rawat N. S. Evaluation of molybdate-polyvinyl alcohol mixtures as inhibitors for mild steel corrosion in synthetic seawater [J]. Bull.Electrochem,1993,9(2﹠3) : 66~68.
[13] Weber T.R. Molybdate Corrosion inhibition in Deaerated and Low-Oxygen Waters [J]. Corrosion .1986,42(9) : 542~545.
[14] 周琼花,周艺. 钼酸盐在中性溶液中缓蚀作用的研究. [J].华北电力技术,2001,(10):25~27.
[15] 于凯,许淳淳. 钼酸钠对铁质文物的缓蚀作用研究. [J].北京化工大学学报,2004,31(4):41~44.
[16] 李宇春,龚洵洁,彭珂如等. 钼酸盐系列缓蚀剂在中性介质中对 A20 碳钢缓蚀的极化曲线研究. [J].工业水处理,2001,21(7):28~29.
[17] 夏春兰,吴田,刘海宁等. 铁极化曲线的测定及应用实验研究. [J].大学化学,2003,18(5):38~41.
[18] 李玉明,刘静敏,马志超等. 钼酸钠与磷酸盐、硅酸盐复配缓蚀剂的研究. [J].腐蚀与防护,2004,25(6) :248~251.
[19] 滕鑫,王莉. 新型缓蚀剂 N-月桂酰肌-L-谷氨酸的合成与性能研究. [J].精细与专用化学品,2003,(23):19~21.
[20] 崔晓莉,江志裕. 交流阻抗谱的表示及应用. [J].上海师范大学学报,2001,30(4):53~61.
[21] 李宇春,龚洵洁,彭珂如. 钼酸盐缓蚀剂在自来水中的电化学行为. [J].材料保护,2001,34(2):10~11.
[22] 史美伦. 交流阻抗谱原理及应用[M]. 北京:国防工业出版社,2001.
[23] 曹楚南,张鉴清. 电化学阻抗谱导论[M]. 北京:科学出版社,2002.
[2] 石声泰,徐克薰,顾皇之. 金属腐蚀和防护的研究发展概况. [J].腐蚀与防护,1980,(1):2~9.
[3] 张兴儒. 油田腐蚀状况与腐蚀控制. [J].腐蚀科学与防护技术,1989,1(2):1~5.
[4] 沈长寿. 钻井液中抗氧缓蚀剂的研究. [J].石油与天然气化工,2000,29(3):139~140.
[5] 傅朝阳,郑家燊,姚安林等. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5):257~263.
[6] 陈理中等译. 美国钻井手册[M]. 北京:石油工业出版社. 1980.
[7] 傅朝阳,郑家燊,姚安林等. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5):257~263.
[8] 候彬,周永璋,魏无际. 钻具的腐蚀与防护. [J].钻井液与完井液,2003,2(2):48~53.
[9] 黄李荣. 钻柱在存放过程中的腐蚀及防腐问题. [J].钻采工艺,2003,26(5):86~87.
[10] Hendrickson J R. Fatigue Studies of Drill Pipe Immersed in Drilling Mud with H2S and CO2 [J]. Final Report, 1984: 88.
[11] 房志忠,彭芳明,刘烈炜等. 钻杆 40Cr 钢在含 H2S 钻井液中的腐蚀疲劳. [J].华中理工大学学报,1995,23(11):148~153.
[12] 吴修斌,李铭瑞,罗富先. 复合缓蚀剂 ZH-1 在中原油田聚合物盐水泥浆中的应用. [J].油田化学,1996,13(2):100~105.
[13] 彭芳明,吕战鹏,吴修兵等. 聚合物盐水泥浆缓蚀剂研究. [J].油田化学,1996,13(2):106~110.
[14] 单江涛,周永璋,魏无际等. G~105 钢在盐水钻井液中的腐蚀行为. [J].材料保护,2004,37(6):44~46.
[15] 华明琪,贺承祖. 钻具的腐蚀与防护. [J].油田化学,1988,5(1):71.
[16] Donbarn J E. Drilling Fluids [J]. Corrosion,1984: 176.
[17] Postagta J R. The sulfate reducing bacteria [M]. Cambridge, University Press, Cambridge, England,1984.
[18] Cormbie D.J,Thomas J D R. Corrosion of iron by sulfate-reducing bacteria [J]. Chemical and Industry. 1980,21(6): 30.
[19] 万里平,孟英峰,梁发书等. 欠平衡钻井中钻具的腐蚀与磨蚀. [J].西部探矿工程,2004,95(4):62~65.
[20] 张天胜. 缓蚀剂[M]. 北京:化学工业出版社,2002: 391~411.
[21] 郑家燊,黄魁元. 缓蚀剂科技发展历程的回顾与展望. [J].材料保护,2000,33(5):11~15.
[22] Walker R. BTA as a Corrosion inhibitor for immersed Cu [J]. Corrosion, 1973,29(7):290.
[23] Salch R M. Corrosion inhibition by naturally occurring substances VⅡ, the effect of aqueous extracts of some leaves & fruit-peels on the Corrosion of steel, Al, Zn and Cu in acid [J]. British Corrosion J, 1982,17(3) :131.
[24] Fouda A S. The role of some thiosemicarbazide derivatives in the corrosion inhibition of Al in HCl [J]. Corrosion Science, 1988, 26(9):719.
[25] 荒牧国次. 缓蚀剂研究 40 年. [J].材料环境,1993,42(5):305.
[26] Vukasovich M S. Application for the versatile molybdate inhibitor [J]. Corrosion Science,1989,29(8):15~17.
[27] Kalman D G. Sodium molybdate as a corrosion inhibitor of mild steel in natural waters [J]. Corrosion,1993,49(8):21~25.
[28] Devasenapath A. Effect of externally added molybdate on repassivation & stress corrosion cracking of type 304 stainless steel in HCl [J]. Corrosion,1996,52(4):243.
[29] Mustafa C M. Corrosion inhibition of Al by molybdate citric acid & nitrite in simulated cooling water [J]. Corrosion Prevention & Control,1997,44(2):49.
[30] 黄魁元,曾兆民. 我国缓蚀剂科学技术十年进展[A]. 中国腐蚀与防护学会成立十周年学术论文集[C]. 北京:中国腐蚀与防护学会,1990.
[31] 郑家燊,齐公台. 我国缓蚀剂研究和应用进展[A]. 第十届全国缓蚀剂学术讨论会论文集[C]. 海口:缓蚀剂专业委员会,1997.
[32] 郑家燊. 水溶性、油溶性和气相缓蚀剂研究与应用情况[J]. 腐蚀与防护,1997,18(5):36.
[33] 陶映初. 一种新型钢材酸浸缓蚀剂(LK-45 植酸提取液)锅炉之酸洗除垢. [J].材料保护,1987,28(4):19~22.
[34] 郭稚弧. 几种植物萃取液对碳钢腐蚀的抑制作用. [J].材料保护,1989,30(2):9~12.
[35] 莫自如,辛剑,汤克峻等. MBT、HEDP、Zn2+与钼酸盐协同缓蚀效应的研究. [J].腐蚀科学与防护技术,1992,4(4):301~320.
[36] 陆柱. 第五届亚太腐蚀控制会议及第廿七届澳洲腐蚀协会年会简介. [J].腐蚀与防护,1988,(3):48~50.
[37] 沈长寿, 熊楚才,黄红兵. 钻具抗氧缓蚀剂的研究. [J].钻井液与完井液,1994,11(4):3~8.
[38] 杨振杰. IADC 钻井液处理剂分类. [J].钻井液与完井液,1997,14(1): 32.
[39] K D Demadis, A Stathoulopoulou. Multifunctional, Environmentally Friendly Additives for Control of Inorganic Foulants in Industrial Water and Process Applications [J]. Materials Performance, 2006,45: 40~44.
[40] Kasper K Ostergaard, Rahim Masoudi, Bahman Tohidi. A general correlation for predicting the suppression of hydrate dissociation temperature in the presence of thermodynamic inhibitors [J]. Journal of Petroleum Science & Engineering,2005,48(1): 70~80.
[41] 缪明富,郭建平,马卫. 90 年代钻井液处理剂发展趋势. [J].钻采工艺,1999,22(4): 57~61.
[42] Y.Tomoe. Unusual corrosion of a drill pipe in newly developed drilling mud during deep drilling [J]. Corrosion, 1999, 55(7) : 706~713.
[43] Bellos, Thomas J. Corrosion inhibitor for highly oxygenated systems[P]. US 4311662, 1982-01-19.
[44] James E.Donham. Chemical control of drilling corrosion [J]. Materials Performance, 1976, 15(10) : 34~38.
[45] M.A.Al-Marhoun. Treatment of drilling fluid to combat drill pipe corrosion [J]. Corrosion, 1990, 46(9) : 778~782.
[46] G.T.Hefter. Organic corrosion inhibitors in neutral solutions; Part 1-Inhibition of steel, copper, and aluminum by straight chain carboxylates [J]. Corrosion, 1997, 53(3) : 657~666.
[47] Dadgar,Ahmad. Corrosion inhibitors for clear, calcium-free high density fluids [P]. US4784779, 1988-11-15.
[48] 赵福祥,范荣增,范旭波等. DPI-03 型钻井液缓蚀剂的研制. [J].油田化学,1996,13(1):37~39.
[49] 刘兴重. 油田高温缓蚀剂 N-(9-菲甲基)喹啉氯化物的合成及复配液缓蚀性能的初步研究. [J].武汉冶金科技大学学报,1996,19(2):165~167.
[50] 徐智谋,郑家燊,董泽华等. 废弃钻井液处理中脱稳药剂对设备腐蚀的影响和控制. [J].材料保护,1999,32(8):29~32.
[51] 唐善法,付绍斌,童伏松等. 复合盐防腐钻井液的研制与现场应用. [J].石油钻采工艺,1998,20(4):41~45.
[52] 唐善法,付绍斌,童伏松等. 复合盐防腐钻井液缓蚀剂 DFP 的研制与应用. [J].油田化学,1997,14(2):110~114.
[53] 唐善法,付绍斌,童伏松等. 复合盐钻井液对钻具的腐蚀机理研究. [J].武汉工业大学学报,1997,19(3):79~82.
[54] 方慧,潘小镛. 缓蚀剂 PF-Ⅰ在加重盐水钻井液中的应用. [J].钻井液与完井液,1997,14(3):36~37.
[55] 黄志宇,何雁,冯英等. 泥浆缓蚀剂 HZ-1 的研究. [J].西安石油学院学报,2001,16(5):54~57.
[56] 沈长寿. 钻井液中抗氧缓蚀剂的研究. [J].石油与天然气化工,2000,29(3):139~140.
[57] 万里平,孟英峰,梁发书. 甲酸盐钻井液对 N80 钢的腐蚀研究. [J].钻采工艺,2003,26(6):83~88.
[58] 郑叔杰,许京国,苏秀纯等. 千米桥潜山小间隙欠平衡钻井液研究. [J].石油钻采工艺,2002,24(1):33~36.
[59] 宋学锋,黄琳,周永璋等. 盐水钻井液中钼酸盐系缓蚀剂对钻杆缓蚀的影响. [J].材料保护,2006,(2):59~62.
[60] 张天胜. 缓蚀剂[M]. 北京:化学工业出版社,2002: 5~10.
[61] 李荻. 电化学原理[M]. 北京:北京航空航天大学出版社,2002: 401~417.
[62] 魏宝明. 金属腐蚀理论及应用[M]. 北京:化学工业出版社,2001: 2~10.
[63] 陈国华,王光信. 电化学方法应用[M]. 北京:化学工业出版社,2003.
[64] 王佳,曹楚南,陈家坚. 缓蚀剂理论与研究方法的进展. [J].腐蚀科学与防护技术,1992,4(2):79~86.
[65] 宋诗哲. 腐蚀电化学研究实验方法[M]. 北京:化工出版社,1988.
[66] 张昭,张鉴清,王建明等. 硫酸钠溶液中 2024-T3 铝合金孔蚀过程的电化学噪声特征. [J].中国有色金属学报,2001,11(2):284~287.
[67] 宣爱国. 电化学噪声测试技术. [J].武汉化工学院学报,2003,25(2):20~22.
[68] 陈旭俊,王海林. 孔蚀缓蚀剂及其理论研究评述(二). [J]. 材料保护,1991,24(8) :4~7.
[69] 王红艳. AES 和 XPS 研究 Cu-Sn-P 镀层表面 PMTA 复合膜. [J].光谱实验室,1999,16(5):480~484.
[70] 严川伟等. 2-巯基苯并恶唑(MBO)在铜表面缓蚀膜研究. [J].中国腐蚀与防护学报,1999,19(6):367~371.
[71] 何新快. 缓蚀剂的研究现状及展望. [J].材料保护,2003,36(8):1~3.
[1] 侯彬. 饱和盐水钻井液缓蚀剂的研究[D]. 南京:南京工业大学,2003.
[2] 魏宝明. 金属腐蚀理论及应用[M]. 北京:化学工业出版社,1984: 115~124.
[3] 李荻. 电化学原理[M]. 北京:北京航空航天大学出版社,1998: 193~211.
[4] 傅朝阳,郑家燊,姚安林. 钻井泥浆中碳钢的腐蚀和防护. [J].石油与天然气化工,2000,29(5) :257~263.
[5] 任文超. 不同晶须分数 Al18B4O33w/Al 复合材料的腐蚀敏感性. [J].应用科技,2004,31(7):10~12.
[6] 刘幼平,夏念勇,赵旭晖. 孔蚀保护电位剖析. [J].中国腐蚀与防护学报,1997,17(4):241~247.
[7] 梁成浩,牟战旗. 模拟体液中 316L 不锈钢和 Co-Cr 合金生物材料腐蚀行为研究. [J].中国生物医学工程学报,2000,19(4):432~435.
[8] 刘继华,李荻,朱国伟等. 7075 铝合金应力腐蚀敏感性的 SSRT 和电化学测试研究. [J].腐蚀与防护,2005,26(1):6~9.
[9] 许淳淳,刘幼平,张晓波等. 孔蚀阴极保护电位测试方法的研究. [J].电化学,1999,5(2):152~156.
[1] 曹楚南. 电化学原理[M]. 北京:化学工业出版社,2004: 117~150.
[2] 柳鑫华,梁英华,芮玉兰. 海水循环冷却水系统钼酸盐及钨酸盐缓蚀剂的研究现状及展望. [J].清洗世界,2006,22(1):20~24.
[3] 苏连芳,金振兴. ATMP、硫脲缓蚀性能研究. [J].锦州师范学院学报(自然科学版),2001,22(2):29~31.
[4] 骆素珍,郑玉贵,敬和民等. NaNO2 对 20SiMn 低合金钢在 3%NaCl 溶液中空蚀损伤的缓蚀作用. [J].腐蚀科学与防护技术,2004,16(6):347~351.
[5] 徐群杰,马姗姗,陈震芳. 钨酸盐及其复配对模拟水中碳钢的缓蚀作用研究. [J].上海电力学院学报,2005,21(3):268~270.
[6] 马欣. 金属在含氯离子水介质中的腐蚀行为. [J].石油化工腐蚀与防护,2005,22(5):5~9.
[7] 许淳淳,何海平. 钨酸钠与十二烷基苯磺酸钠协同缓蚀作用研究. [J].表面技术,2005,34(3):33~35.
[8] 王慧龙,姜文凤,郑家燊. 巯基三唑化合物与有机季铵盐的缓蚀协同效应. [J].材料保护,2006,39(1):9~11.
[9] 张丽华. 用线性极化法研究金属材料在天然碱苛化体系中的腐蚀行为. [J].内蒙古石油化工,2002,(27):42~47.
[10] N.Bui,A.Irhzo,F.Oabosi and Y.Limouzin-Maire. On the Mechanism for Improved Passivation by Additions of Tungsten to Austenitic Stainless Steels [J]. Corrosion,1983,39(12): 491~496.
[11] 杨文庆. 钼酸钠系缓蚀剂的进展. [J].材料保护,1996,28(8): 16~18.
[12] Patnaik, S.R. Vdayabhanu,G.Rawat N. S. Evaluation of molybdate-polyvinyl alcohol mixtures as inhibitors for mild steel corrosion in synthetic seawater [J]. Bull.Electrochem,1993,9(2﹠3) : 66~68.
[13] Weber T.R. Molybdate Corrosion inhibition in Deaerated and Low-Oxygen Waters [J]. Corrosion .1986,42(9) : 542~545.
[14] 周琼花,周艺. 钼酸盐在中性溶液中缓蚀作用的研究. [J].华北电力技术,2001,(10):25~27.
[15] 于凯,许淳淳. 钼酸钠对铁质文物的缓蚀作用研究. [J].北京化工大学学报,2004,31(4):41~44.
[16] 李宇春,龚洵洁,彭珂如等. 钼酸盐系列缓蚀剂在中性介质中对 A20 碳钢缓蚀的极化曲线研究. [J].工业水处理,2001,21(7):28~29.
[17] 夏春兰,吴田,刘海宁等. 铁极化曲线的测定及应用实验研究. [J].大学化学,2003,18(5):38~41.
[18] 李玉明,刘静敏,马志超等. 钼酸钠与磷酸盐、硅酸盐复配缓蚀剂的研究. [J].腐蚀与防护,2004,25(6) :248~251.
[19] 滕鑫,王莉. 新型缓蚀剂 N-月桂酰肌-L-谷氨酸的合成与性能研究. [J].精细与专用化学品,2003,(23):19~21.
[20] 崔晓莉,江志裕. 交流阻抗谱的表示及应用. [J].上海师范大学学报,2001,30(4):53~61.
[21] 李宇春,龚洵洁,彭珂如. 钼酸盐缓蚀剂在自来水中的电化学行为. [J].材料保护,2001,34(2):10~11.
[22] 史美伦. 交流阻抗谱原理及应用[M]. 北京:国防工业出版社,2001.
[23] 曹楚南,张鉴清. 电化学阻抗谱导论[M]. 北京:科学出版社,2002.