Synergistic effects in the inhibition by chromate-containing mixtures of the corrosion of mild steel

Hazzaa, M. I.

January 1987

No description available.

669

Steel corrosion inhibition

Inhibition of mild steel corrosion in cooling systems by low- and non-toxic corrosion inhibitors

Ahmed, Mohamed

January 2017

The aim of the research in this thesis was to study how environmentally friendly corrosion inhibitors for cooling water systems might be developed and used. Firstly, reduced toxicity inorganic corrosion inhibitors (i.e. nitrite/molybdate) were considered. Secondly, non-toxic inhibitors based on mono and di-basic salts of carboxylic acids were studied systematically as a function of carbon chain length. For nitrite inhibitor alone, a concentration of 7 mM NaNO2 was effective to inhibit carbon steel in chloride media of 10 mM NaCl, while 10 mM nitrite was needed in sulphate media of 3.66 mM Na2SO4. However, it was found possible to significantly reduce the concentration of nitrite by adding molybdate in synergy. This was attributed to the nitrite passivation combined with ferrous molybdate salt film pore plugging thus promoting a continuous and protective film on the material within these media. Thus, in pH 6-10 an inhibition efficiency of 97% was recorded with a mixture of 3 mM nitrite/2 mM molybdate in both chloride and sulphate media and at 25°C and 60°C. However as the solution pH decreased below pH 4 the inhibition efficiency decreased to about 47%.In the second part of the study, the use of sodium salts of carboxylic acids with different chain lengths has been investigated. In this part a summary of the performances and limitations of both mono- and di-sodium carboxylate inhibitors are presented. For mono-carboxylates, the inhibition efficiency reached a maximum value of 95% in stagnant aerated solutions at a chain length of C=4 with a critical inhibition concentration of 6 mM in 10 mM NaCl solution. However the inhibition efficiency gradually decreased as the number of carbon atoms in the chain length increased to more than 8, or less than 4, and this was in agreement with surface hydrophobicity and contact angle results. For lower chain lengths, the carboxylate anion becomes more acidic and complexing of the metal ion while for longer chain lengths, the carboxylate anion becomes less soluble and tends to micellise wherby the active groups are no longer available for surface adsorption. For di-carboxylates the inhibition efficiency improved in 10 mM NaCl at a given chain length compared with mono-carboxylates, and continued to increase to C=8 (sebacate), which achieved excellent inhibition efficiency. However, sebacate is costly so a blend with ethyl hexanoate was found to be economically favoured.

620

Reavalia??o da efici?ncia de ?leo de coco saponificado e de sua microemuls?o como inibidores de corros?o em uma c?lula eletroqu?mica

Rocha, Thiago Ramalho da

25 April 2008

Made available in DSpace on 2014-12-17T15:41:43Z (GMT). No. of bitstreams: 1 ThiagoRR.pdf: 1895833 bytes, checksum: 59d0cd6d03df2b5c8165e3ae0bf39a80 (MD5) Previous issue date: 2008-04-25 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / An interesting development in surfactants science and technology is their application as corrosion inhibitors, since they act as protective films over anodic and cathodic surfaces. This work aims to investigate the efficiency of saponified coconut oil (SCO) as corrosion inhibitor and of microemulsified system (SCO + butanol + kerosene oil + distilled water), in saline medium, using an adapted instrumented cell, via techniques involving linear polarization resistance (LPR) and mass loss coupons (MLC). For this, curves of efficiency versus SCO concentration (ranging between 0 and 75 ppm) have been constructed. According to the obtained results, the following efficiency levels were reached with OCS: 98% at a 75 ppm concentration via the LPR method and 95% at 75 ppm via the MLC method. The microemulsified system, for a concentration of 15 ppm of SCO, obtained maximum inhibition of 97% (LPR) and 93% (MLC). These data indicate that it is possible to optimize the use of SCO in similar applications. Previous works have demonstrated that maximal efficiencies below 90% are attained, typically 65% as free molecules and 77% in microemulsified medium, via the LPR method in a different type of cell. Therefore, it can be concluded that the adapted instrumented cell (in those used methods) showed to be an important tool in this kind of study and the SCO was shown effective in the inhibition of the metal / Tensoativos v?m sendo alvo de interesse como inibidores de corros?o, pois funcionam como pel?culas protetoras sobre ?reas an?dicas e cat?dicas. Este trabalho teve como objetivo avaliar a efici?ncia de inibi??o ? corros?o do tensoativo ?leo de coco saponificado (OCS) e do sistema icroemulsionado (OCS + butanol + querosene + ?gua destilada), em meio salino, utilizando-se uma c?lula instrumentada adaptada. A efic?cia do OCS foi avaliada utilizando-se os m?todos de resist?ncia de polariza??o linear (LPR) e cupons de perda de massa (CPM), tendo sido constru?das curvas de efici?ncia versus concentra??o de OCS (variando de 0 a 75 ppm). De acordo com os resultados obtidos, verificou-se que este tensoativo apresenta a seguinte ordem de efici?ncia de inibi??o ? corros?o: para uma concentra??o de 75 ppm, 98% pelo m?todo LPR e 95% pelo m?todo CPM. O sistema microemulsionado, para uma concentra??o de 15 ppm de OCS, obteve inibi??o m?xima de 97% (LPR) e 93% (CPM). Atrav?s deste trabalho foi poss?vel otimizar o uso do tensoativo OCS, que em trabalhos anteriores mostrou efic?cia m?xima inferior a 90% (63% na sua forma livre e 77% na sua forma microemulsionada, pelo m?todo LPR, em um outro tipo de c?lula). Conclusivamente, pode-se dizer que a c?lula instrumentada adaptada (nos m?todos utilizados) provou ser uma ferramenta importante neste tipo de estudo e o OCS mostrou-se efetivo na inibi??o do metal

?leo de coco saponificado

Microemuls?o

Inibi??o de corros?o de a?o carbono

Resist?ncia de polariza??o linear

Cupons de perda de massa

Saponified coconut oil

Microemulsion

Carbon steel corrosion inhibition