Effects of acid types on the recycling of used lubricating oil
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Used Lubricating Oil Recycling
- 2.2Types of Acids used in Oil Recycling
- 2.3Environmental Impact of Used Oil
- 2.4Current Practices in Oil Recycling
- 2.5Chemical Reactions in Oil Recycling with Acids
- 2.6Efficiency of Different Acid Types
- 2.7Economic Considerations in Oil Recycling
- 2.8Regulations and Standards in Oil Recycling
- 2.9Innovations in Oil Recycling Techniques
- 2.10Comparative Analysis of Acid Types
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Design
- 3.2Sampling Techniques
- 3.3Data Collection Methods
- 3.4Data Analysis Procedures
- 3.5Experimental Setup
- 3.6Variables and Controls
- 3.7Ethical Considerations
- 3.8Statistical Tools
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Acid Type A Results and Discussion
- 4.2Acid Type B Results and Discussion
- 4.3Acid Type C Results and Discussion
- 4.4Acid Type D Results and Discussion
- 4.5Comparison of Acid Types Results
- 4.6Implications of Findings
- 4.7Recommendations for Practice
- 4.8Future Research Directions
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of Findings
- 5.2Conclusion
- 5.3Contributions to Knowledge
- 5.4Practical Implications
- 5.5Recommendations
Project Abstract
The recycling of used lubricating oil is a crucial process to reduce environmental pollution and conserve resources. This study investigated the effects of different acid types on the recycling of used lubricating oil. Sulfuric acid, hydrochloric acid, and acetic acid were chosen as representative acids to assess their impact on the oil recycling process. The study involved the acid treatment of used lubricating oil samples followed by various separation and purification techniques to evaluate the efficiency of each acid type. The results indicated that the acid type significantly influenced the quality of the recycled lubricating oil. Sulfuric acid treatment showed the highest efficiency in removing impurities and contaminants from the used oil, resulting in a higher quality of the recycled product compared to hydrochloric acid and acetic acid treatments. The sulfuric acid treatment also exhibited better performance in terms of viscosity, flash point, and total acid number of the recycled oil. Furthermore, the study examined the economic feasibility of using different acid types for the recycling process. Cost analysis revealed that sulfuric acid treatment, despite being slightly more expensive than hydrochloric acid and acetic acid treatments, provided better overall results and higher quality recycled oil. The higher efficiency and quality of the recycled oil obtained through sulfuric acid treatment could justify the higher initial investment in this acid type. Overall, the findings of this study emphasize the importance of acid selection in the recycling of used lubricating oil. Sulfuric acid demonstrated superior performance in terms of removing impurities, improving oil quality, and enhancing economic feasibility compared to hydrochloric acid and acetic acid. These results provide valuable insights for optimizing the recycling process and promoting sustainable practices in the lubricating oil industry. Further research is recommended to explore additional acid types and optimize the recycling parameters for enhanced efficiency and environmental benefits.
Project Overview
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</p><p>This study focused on the effects of acid types on the recycling of used lubricating oil. Three different acids, H2SO4, HCl, and HNO3 were used for the treatment of used lubricating oil and subsequent neutralization of the oil with NaOH. The properties of fresh and used oil tested for were kinematic viscosity at 40 OC and 100 OC, viscosity index, flash point, pour point, specific gravity at 40 OC, water content, sulphur content, total base number (TBN), and metals present (Pb, Zn and Cu). The result obtained revealed that the quality of lubricating oil was affected after usage as a result of its property degradation and presence of heavy metals such as Pb, Zn and Cu. The result obtained shows that treatment of used oil with acids greatly improved the quality of the used oil. The extent of the recycled oil quality improvement and its yield varied with acid type. The result showed that flash point increased from 220 OC for used oil to 232 OC, 225 OC and 227 OC for oil sample recycled with H2SO4, HCl and HNO3 respectively. This is compared with 245 OC for fresh oil. Also, viscosity index increased from 91.2 for spent oil to 125, 116 and 119 for oil sample recycled with H2SO4, HCl and HNO3 respectively. It was also compared with 127 of fresh oil. Sulfur content was reduced to 0.046, 0.2 and 0.35 wt % using H2SO4, HCl and HNO3 for used oil treatment. In general, based on the various characterization analysis conducted in this study, acid treatment efficiency of used lubricant with H2SO4 is the best followed by HNO3 and HCl respectively. However, the use of H2SO4 also gives the highest yield of 70 % recycled oil.</p><p>Keywords: Lubricating oil, used oil, recycled oil, treatment, viscosity, oil characteristics</p><p>Lubricant is an oil or grease that is applied as a surface coating to moving parts to protect and reduce friction of two surfaces in relative motion, eliminate temperature build up and keep the engine clean (Toolingu, 2013; Udonne 2011; Ogbeide, 2010). It also serves the purpose of transportation of foreign particles, heat transfer, corrosion prevention, cutting of metal and protection against wear (Udonne 2011; Ogbeide, 2010). The lubricating oils are either bio or petroleum based and the petroleum base feedstock are mainly complex mixtures of hydrocarbon molecules (Udonne, 2011; Hamad et al., 2005) ranging from low viscosity oils to high viscosity lubricating oil. T.Y chemicals (1990) analysis shows that the presence of impurities depends on the petroleum process and production method but concluded that lube oil contains aromatics in the range 4 to 12 % free, sulphur and other impurities. Machineries/engines that make use of oil lubricant include all vehicles, motor bikes, generating plants and it is also used in various industries/factories equipments. Spent oil is any petroleum-based or synthetic oil that has been used and as a result, is contaminated and has lost nearly all its physical or chemical properties but do not wear out and the contaminant present in it can be removed to the point that it can be reused as engine or machine oil (Garthe, 2005). Contaminants or impure lubricants are drained off from cars and disposed off as used or waste oil containing undesirable oxidation product, sediments, metallic wear particles, water, degraded additives and lead hazardous substances (James, 1967; Kamal and Khan, 2009; Durrani et al., 2011; Emam and Shoaib, 2012; Abdulkareem et al., 2014).</p><p>Disposal of used oil into the environment, used as weed killers, pouring into ditches or dumping illegally is dangerous to life. It contaminates water as research shows that a gallon of used oil can contaminate one million gallons of water. Used oil can also affect plant life if poured on the ground and it sinks down into the water table (EPA 530-F-94-008). It is therefore obvious that indiscriminate disposal of used lubricating oil into the environment constitutes hazards to both fauna and flora. Hence, the need to recycle used lubricating oil. There have been several approaches in an attempt to regenerate used lubricants (Isah et al., 2013; Abdulkareem et al., 2014; Durrani et al., 2011 Jhanani and Joseph, 2011; Ogbeide, 2010; Josiah and Ikiensikimama, 2010; Abdul-Jebbar et al., 2010; Kamal and Khan, 2009; Rahman et al., 2008; Gorman, 2005).</p><p>Industries and private users of lubricating oils demand necessitates the need to find ways of regenerating the oil after use due to the rapid depletion of fossil fuel reserve which is the source of oil feedstock, shortage of fresh oil, price increase and high demand (Zambiri, 1988). The increased use of lubricating oil globally for which Nigeria produces 364 166 000 litres of used oil annually disposed as a common practice into gutters, water drains, open plots and farms which led to streams, ground water, lakes and oceans pollution (Isah et al., 2013; EPA 530-F-94-008). The frequent disposal of waste lubricating oils globally is alarming and requires serious attention. Presently, many countries in the world are presently giving serious attention to the problems of environmental degradation and hazards caused by the disposal of waste lubricating oils (Hamad et al., 2005; Jilner, 1997). T.Y Chemicals (1990) referred regeneration of used lubricating oil as the means of removal of contaminants or impurities by sulphonating agents such as sulphuric acid, oleum or sulphur trioxide and concluded that the process is made up of two cycles, the removal of about 80 % aromatics and other impurities in the first cycle and other 20% impurities in the second operation cycle. However, Isah et al. (2013) carried out regeneration of used engine oil treated with sulphuric acid and bleached using industrial bleaching earth and activated carbon for different formulated grades. The results obtained by the group showed that the best grade in comparison with fresh oil in terms of viscosity, specific gravity and total acid number was obtained using industrial bleaching earth. Abdulkareem et al. (2014) compared the performance efficiency of used lubricating oil treatment methods and concluded from their findings that acid and acid/clay treatment methods were the most attractive with consequences of environmental pollution resulting from acid sludge. Emam and Shoaib (2012) also made comparison between acid/clay percolation and solvent/clay methods of recycling lubricating oils and concluded that the used of acid treatment method was the most attractive interms of quality while solvent method gave the highest yield.</p><p>The used of sulphonating agents specifically sulphuric acid to treat used lubricant has been fully established by many researchers (Abdulkareem et al., 2014; Isah et al., 2013; Emam and Shoaib, 2012) and its performance has been very competitive but environmental consequences are part of its major limitations. In addition to environmental consequences, there is a dare need to quantitatively and qualitatively analyze the effect of other acids which suggest in this study the investigation of nitric, sulphuric and hydrochloric acids suitability and effects in the treatment stage of used lubricating oil recycling.</p>
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