表面技术
錶麵技術
표면기술
Surface Technology
2015年
10期
93-98
,共6页
王文峰%丁芳君%刘丹婷%周晓荣%李建芬
王文峰%丁芳君%劉丹婷%週曉榮%李建芬
왕문봉%정방군%류단정%주효영%리건분
碳钢%缓蚀%植酸%吐温-40%失重法%电化学%协同作用
碳鋼%緩蝕%植痠%吐溫-40%失重法%電化學%協同作用
탄강%완식%식산%토온-40%실중법%전화학%협동작용
carbon steel%corrosion inhibition%phytic acid%Tween-40%weight-loss method%electrochemistry%synergistic effect
目的:提高0.5 mol/L HCl中植酸对热轧碳钢( HRCS)的缓蚀性能。方法用失重法和电化学阻抗法测试植酸、吐温-40以及复配缓蚀剂的缓蚀效率,从热力学和动力学方面分析复配缓蚀剂的作用机制。结果失重法测试表明,植酸和吐温均对热轧碳钢有一定缓蚀作用。当293 K,植酸质量浓度为0.3 g/L时,缓蚀效率达到69.1%,在质量浓度为0.8 g/L时缓蚀效率下降为9.6%;吐温-40的缓蚀效率随着质量浓度的增大而增大,0.8 g/L时达到73.4%。在0.5 mol/L盐酸中加入0.05 g/L吐温-40后,复配缓蚀剂的缓蚀效率随着质量浓度的增加而增大,且优于植酸和吐温-40单独使用,表现出协同效应。电化学测试得到了相同的结论,表明复配缓蚀剂在碳钢表面产生自发的Langmuir吸附,使碳钢腐蚀反应的活化能增大,是熵减少的放热过程。结论吐温-40和植酸在盐酸中对热轧碳钢的腐蚀有缓蚀协同作用。
目的:提高0.5 mol/L HCl中植痠對熱軋碳鋼( HRCS)的緩蝕性能。方法用失重法和電化學阻抗法測試植痠、吐溫-40以及複配緩蝕劑的緩蝕效率,從熱力學和動力學方麵分析複配緩蝕劑的作用機製。結果失重法測試錶明,植痠和吐溫均對熱軋碳鋼有一定緩蝕作用。噹293 K,植痠質量濃度為0.3 g/L時,緩蝕效率達到69.1%,在質量濃度為0.8 g/L時緩蝕效率下降為9.6%;吐溫-40的緩蝕效率隨著質量濃度的增大而增大,0.8 g/L時達到73.4%。在0.5 mol/L鹽痠中加入0.05 g/L吐溫-40後,複配緩蝕劑的緩蝕效率隨著質量濃度的增加而增大,且優于植痠和吐溫-40單獨使用,錶現齣協同效應。電化學測試得到瞭相同的結論,錶明複配緩蝕劑在碳鋼錶麵產生自髮的Langmuir吸附,使碳鋼腐蝕反應的活化能增大,是熵減少的放熱過程。結論吐溫-40和植痠在鹽痠中對熱軋碳鋼的腐蝕有緩蝕協同作用。
목적:제고0.5 mol/L HCl중식산대열알탄강( HRCS)적완식성능。방법용실중법화전화학조항법측시식산、토온-40이급복배완식제적완식효솔,종열역학화동역학방면분석복배완식제적작용궤제。결과실중법측시표명,식산화토온균대열알탄강유일정완식작용。당293 K,식산질량농도위0.3 g/L시,완식효솔체도69.1%,재질량농도위0.8 g/L시완식효솔하강위9.6%;토온-40적완식효솔수착질량농도적증대이증대,0.8 g/L시체도73.4%。재0.5 mol/L염산중가입0.05 g/L토온-40후,복배완식제적완식효솔수착질량농도적증가이증대,차우우식산화토온-40단독사용,표현출협동효응。전화학측시득도료상동적결론,표명복배완식제재탄강표면산생자발적Langmuir흡부,사탄강부식반응적활화능증대,시적감소적방열과정。결론토온-40화식산재염산중대열알탄강적부식유완식협동작용。
Objective To improve the corrosion inhibition performance of phytic acid for hot rolled carbon steel (HRCS) in 0. 5 mol/L HCl soltuion. Methods The corrosion inhibition efficiency of phytic acid, Tween-40, and their compound on carbon steel was measured by weight-loss method and electrochemical impedance spectrometry tests. The inhibition mechanism of the compound inhibitor was analyzed using thermodynamics and kinetics. Results It was revealed by weight-loss measurement that either phytic acid or tween-40 alone had limited inhibitory effect on the corrosion of HRCS in hydrochloric acid. The inhibition efficiency of phy-tic acid reached the max value of 69. 1% when the concentration was 0. 3 g/L at 293 K, then decreased with further addition of in-hibitor and was reduced to 9. 6% when the concentration of phytic acid was 0. 8 g/L. On the other hand, the inhibition efficiency increased with the increase of the tween-40's concentration, which reached the value of 73. 4% at 0. 8 g/L, 293 K. When Tween-40 (0. 05 g/L) was added into the solution, the inhibition efficiency of the compound inhibitor increased even if the concentration of phytic acid exceeded 0. 3 g/L. The corrosion inhibition efficiency of compound inhibitor was higher than the sum of phytic acid's and Tween-40's efficiency, which suggested synergistic effect. The same result could be concluded from electrochemical impe-dance spectrometry measurement. Further analysis revealed that the adsorption of the compound inhibitor on the surface of carbon steel obeyed Langmuir adsorption isotherm equation, which improved the activation energy( Ea ) of the corrosion procession, leading to the decrease of entropy. Conclusion Tween-40 and phytic acid showed synergistic corrosion inhibition effect on the HRCS in hy-drochloric acid.
