(转)等离子体技术应用于燃料油加工的研究进展

石油学报(石油加工)
2018 年 3 月 ACTA PETROLEI SINICA (PETROLEUM PROCESSING SECTION) 第 34 卷第 2 期 文章编号：1001-8719(2018)02-0430-11
等离子体技术应用于燃料油加工的研究进展
郭明1,孙强1,刘爱贤成，郭绪强1，2
(1-中国石油大学重质油国家重点实验室，北京102249； 2.中国石油大学(北京)克拉玛依校区，新疆克拉玛依834000)
摘要：由于原油需求逐年增加且原油劣质化现象不断加重，传统的原油加工方式面临着巨大的挑战。作为一项新 兴技术，近年来等离子体技术应用于燃料油加工成为了行业内的热点话题。总结了近期等离子体技术应用于燃料 油加工的研究进展；介绍了不同结构的反应器；讨论并比较了放电类型、工作气体、反应器结构、电压及功率等 各项参数对实验结果的影响。结果表明，氧气与富氢气体的混合气最适宜作为工作气体，且输出功率及气体产率 均会随着电压的增加而增加。归纳了目前等离子体技术在应用于油品加工方面存在的问题，指出今后的研究方向， 并对研发前景进行了展望。
关 键 词：等离子体；重质碳氢化合物；反应器；反应参数；改质
中图分类号：TE62 文献标识码：A doi： 10. 3969/j. issn. 1001-8719. 2018. 02. 026
Review of Plasma Technology on Fuel Oil Processing
GUO Ming1 , SUN Qiang1 , LIU Aixian1'2 , GUO Xuqiang1'2
(1. State Key Laboratory of Heavy Oil Processing , China University of Petroleum, Beijing 102249, China ；
2. China University of Petroleum at Karamay , Karamay 834000, China)
Abstract: Oil production declination and inferior oil quality challenge the traditional crude oil processing, and prompt the researches of novel technologies. In this case, the application of plasma for oil processing has emerged and become a hot topic in petroleum industry. This paper mainly summarizes the recent progress on plasma assisted oil processing and various related reactors. Furthermore, a large number of parameters are compared and discussed, including the discharge type, working gas, structure of reactors, voltage and power. Studies show that a mixture of argon and hydrogen rich gas is the desired working gas, and gas production and input power are increasing along with the enhancement of voltage. Finally, some suggestions and prospects are proposed to direct potential research orientations in future work.
Key words： plasma； heavy hydrocarbons； reactors； parameters； reforming

1Introduction
Fuel oil contains a wide range of products, from heating oil to residual fuel oil. It is well established that the worldwide consumption of oil
products is increasing year by year with the growth of the population. In China, oil consumption has surged from 190 Mt to 550 Mt during the past twenty years, while the output of oil has remained the same. Therefore, external dependence of oil
was gradually being increased, and by the end of 2016 it had reached 65. 2%[1]. In 1997 the output of oil in China was about 150 Mt, while in 2015 it was only 220 Mt⑵.What is more, nearly 28% of the products are heavy oil[3]. At world scale, nearly 70% of the oil products are heavy oil '幻. Such a high ratio demonstrates that how to make use of heavy oil becomes a problem we cannot avoid. There are more serious challenges when it comes to technology and economy, due to the high viscosity, high relative molecular mass and complex components of fuel oil . Therefore, fuel oil processing has become an important focus in recent years.
Traditionally, there are two main ways to process fuel oil, involving hydrogenation and decarbonization. The first step of hydrogenation process is to break down big molecules into saturated or aromatic free radicals, under the effects of heat and catalyst. Then, adding activated hydrogen to the free radicals to prevent them from becoming condensed. Meanwhile, removing sulfur, nitrogen and other harmful impurities by converting them into hydrogen sulfide, ammonia, ect, occurred. Decarbonization process includes viscosity breaking, coking, solvent deasphalting and catalytic cracking ⑹. However, there are many technical problems that influence efficiency and economy for both hydrogenation and decarbonization processes. For example, hydrogenation process has higher requirements for feed oil viscosity because of the poor dissolving capacity and diffusion velocity of hydrogen in residual oil. Therefore, light oil needs to be mixed with heavy oil before processing, which significantly increases the investment. Decarbonization route faces the complex problem of coking. Almost all kinds of asphaltene will form coke in the process of catalytic cracking. And it can only be applied to process raw materials with low impurities. That is, the mass fraction of carbon residue should be lower than 6 % , and the mass fraction of nickel and vanadium should be lower than 35 gg/g[7]. The residual oil with high content of sulfur and metal must be pretreated before catalytic cracking. Although delayed coking has many advantages, like low investment and wide adaption for raw materials, it has low yiled of high added value products. High yield of diesel in delayed coking process doesn' t match the decreasing rate ratio of diesel to gasoline in market[8]. Therefore, it is urgently necessary to develop a new way to process the fuel oil.
Plasma is a new and thriving technology in recent years. Known as the “ fourth stage of matter", plasma is a kind of gaseous substance produced by ionized atoms or an atomic group that partially lost electrons . Due to the excited state of particles in plasma, it usually has very high energy density, which makes the breakage and recombination of the big molecules become possible[10]. Due to the above characteristics it has been applied to oil processing to reduce viscosity and obtain specific ideal target products , especially for H2 , Q H2 , and other light gaseous hydrocarbons 口幻. A lot of achievements have been made in recent years.
In this paper, researches on processing oil using plasma in recent years are summarized, which are based on the highlighted problems and directions in this area.
2Development of plasma cracking hydrocarbons
2. 1 Non-thermal equilibrium plasma
2. 1. 1 Dielectric barrier discharge plasma
Ling et al. treated heavy oil with air and argon in the quartz reactor made by themselves . After this process, a rotational viscometer and infrared spectroscopy were used to analyze the product oil. Gas chromatography was also used to analyze the gas products. The infrared spectra show that oxygen-containing groups become increased, which infers that there are oxidation reactions occurred when subtracts are treated with air. When treated with argon, both cracking reactions and polymerization occurrs. The viscosity of heavy oil is increased because of polymerization and oxidization. But, many gases, like H2 ? CH4 , and C2 H2 are
produced when oil is treated with argon. The sum of H2 and CH4 makes up more than 70% of the whole gas products, indicating that plasma is a promising method to process oil.
Hao et al. used a cylindrical dielectric barrier discharge plasma reactor, as shown in Fig. 1. It mainly consists of a high voltage electrode 9 quartz tube barrier, ground electrode 9 furnace 9 insulating flange and gas distributor. A reaction chamber is formed by two electrodes and insulating flanges. Both electrodes are connected to the plasma power supply. A quartz tube is used as a dielectric barrier. An electric furnace is fixed on the outside of the reactor, with a temperature controller to make the heavy oil be able to flow. A gas distributor is placed on the bottom of the reactor to generate bubbles. These bubbles can mix with heavy oil to increase the phase interface area and facilitate the ionization of gas.
The sample was preheated at a certain temperature9 usually between 160°C and 240°C ,
the reactor. N2 ? H2 ? CH4
working gases and fed chamber through the gas Then, heavy hydrocarbons the electric field and high temperature. After the experiment, light oil is collected as a condensable product and residue remaining at the bottom is also collected as heavy oil.
Fig. 1 Schematic of the cylindrical DBD plasma
reactor suggested by Hao[16]
This study indicates that intra-molecular condensation is the main reaction in the plasma-on condition, rather than inter-molecular condensation, thus plasma increases oil yield significantly. Taking Liaohe's residues as an example 9 the results show that light oil are still produced because of the heat in the plasma-off runs, with the yield ranging from 25% to 30%. In comparison 9 in the plasma-on runs, the yield of light oil is about 48%, increasing by 20 percentage when hydrogen-rich gas is applied. But, the yield of light oil only increases 10 percentage with N2 plasma, which demonstrates that H2 , CH4 and C2 H6 plasma have higher reactivity than N2 plasma . Some experimental data is shown in Fig. 2.
Mohammd et al. 口里 studied the effect of dielectric barrier discharge plasma on processing oils through using zz-hexadecane as a model compound of heavy oil. The experimental setup is shown in Fig. 3. The reactor consists of an aluminum rod as a high voltage electrode 9 stainless steel wire as a low voltage electrode 9 and a quartz tube as a dielectric. Gas chromatography and a mass spectrometry detector were used to analyze the products with the change of gas type, voltage9 and gas flow. The results show that zz-hexadecane is cracked into both light and heavy hydrocarbons. But, the percentage of the light product (Ci6- ) is larger than that of the heavy one (Ci6+ ) in general.
The same setup was used by Mohammd to crack lubricating oil and heavy oil in order to make further progress[19]. Besides gas chromatography, a simulated

Fig. 3 Schematic of the dielectric barrier discharge (DBD) plasma reactor suggested by Mohammd[18]
DBD一Dielectric barrier discharge； OES—Optical emission spectroscopy；
H V—High voltage ； GC—Gas chromatography ； MS、Mass spectroscopy

distillation analyzer was also used to detect the evaporation temperature of various samples.
The results show that hydrogen, ethylene, and propylene are produced when lubricating oil and heavy oil
The simulated distillation analyzer 95% of raw oil and lubricating oil are eluted in 510°C and 464°C , respectively, showing 46°C differences in the boiling point distributions. While, the heavy oil showed 169°C differences when 95% of raw and lubricating oil are eluted. This is because lighter hydrocarbons, with lower boiling points, are produced under the plasma.
Considering the previous works, Mahtab et al. I?。] studied the process of treating fuel oil with methane and ethane by using a barrier discharge plasma torch, to improve the selectivity of products. The effect of working gas flow, various ratios of the working gas and different working gases were investigated. The results show that the production rate of lighter hydrocarbons increases from 1. 72 to 10. 48 mL/min for 4000 mL/min argon plus 400 mL/min methane as the working gas. And the selectivity of C3 — C5 is increasing with the decreasing of the Ar/CH4 ratio. By changing the type of working gas from methane to ethane 9 the production rate of light hydrocarbons increases from 3. 53 to 13. 5 mL/min. Therefore9 ethane has a better performance than methane 9 and it was more suitable as a working gas.
2. 1. 2 Glow discharge plasma
Zhang et al.堂口 reported a method for reducing the viscosity of heavy oil with a catalyst using plasma. In his method, heavy oil and a transitional metal catalyst are placed in a quartz tube, with a volume ratio ranging from 3 to 1, to 3 to 10. The quartz tube is fixed in the plasma discharge device. Then, the tube is treated with a vacuum pump until the vacuum degrees reaches 60X10 ? kPa. Finally 9 the discharge device starts to process the heavy oil with the working gases, like H2 , CH4 , and N? and so on. The discharge voltage can range from 80 to 120 V and processing time can be adjusted from 0. 5 h to 3 h. A rotational viscometer is used to determine the viscosity of the heavy oil before and after the reaction. The patent takes H2 as the working gas for an example ? and the results show that viscosity decreases by 57. 55% maximally. Part of the experimental data is shown in Table 1.
This patent provides an easy and green way to reduce the viscosity of heavy oil, which is beneficial to flow.

Table 1 Viscosity change of heavy oil after processing""
Number Reaction time/h Viscosity before reaction/
(mPa • s) Viscosity after reaction/ (mPa , s) Rate of viscosity reduction/ %
1 1. 5 2080 920 55. 76
2 1. 5 3072 1304 57. 55
3 1. 5 2436 1044 56. 93
4 1. 5 2388 1283 53. 76

2. 1. 3 Microwave plasma
      Mohammad^] investigated cracking fuel oil using a microwave plasma torch. The schematic of the microwave plasma torch setup is shown in Fig. 4. As demonstrated in the previous studies, light products like hydrogen and G—C4 compounds are produced during the process. But the selectivity of products doesn't show a certain trend with the change of gas flow rate and power.

Fig. 4 Schematic of the microwave plasma torch suggested by Mohammad[22]

2.2 Local thermal equilibrium plasma
Li et al. used a non-transferred arc plasma torch reactor 9 which was designed by Cheng[24] , to process coal tar for obtaining acetylene in argon and hydrogen mixed gas, as shown in Fig. 5. The plasma torch is discharged between the cathodes and jetted directly into the reactor. This processes coal tar that is loaded through the inlet at the top of the downer reactor. Some important factors, like feedstock injection temperature9 working gas and coal tar enthalpy were investigated according to the pyrolysis performance. The results reveal that coal tar is directly converted to acetylene and other gaseous products with conversion rates reaching maximums of 86. 3%. The maximum yields of light gas and acetylene are 51. 7% and 24.6%, respectively. Furthermore 9 ethylene is also generated as by-product with the yield of 7. 9%.
Cheng® *] created a 2 MW pilot scale thermal plasma reactor designed by Chen®〕to study asphaltene pyrolysis in the atmosphere of argon and hydrogen9 which is shown in Fig. 6. The results show that the optimal feed rate of asphaltene is about 407 kg/h, with the producing of acetylene at the speed of 210 kg/h. Temperature of pyrolysis gas, effective mass ratio of C/H, and inert factors, are key points of this experiment. The addition of hydrogen and decoking gases decrease the effective mass ratio of C/H, and thereby influence the production of acetylene. Thus, the extra rate of hydrogen should be less than 15 kg/h and that of decoking gases should be less than 50 kg/h. Further study also indicates that adding a little of asphaltene or mixing coal tar to coal can improve the performance of coal pyrolysis 9 leading to more acetylene

Cathode
/ ______ Insulation materials

production and less energy consumption. Co-cracking coal tar and asphaltene by plasma can be used as a supplementary means to complement coal chemical industry and petrochemical industry. Consequently, thermal plasma provides a potential way to process bulk chemical materials with universal adaptability. But how to effectively improve performances under the same total amount of energy input is still worth to be explored.

Fig. 6 Schematic of the 2MW plasma reactor designed by Chen[27]

3Discussion on the influence of parameters on performances
Performance is defined as the conversion rate of fuel oil in this paper. Various parameters affect conversion rate9 including discharge type, reactor structure ? fuel property, voltage and power, working gas and so on.
3. 1 Discharge types
In the field of fuel oil processing, there are four discharge types, radio frequency discharge9 arc, microwave? and dielectric barrier discharge9 which have been investigated for many years.
Amouroux et al.詩8 29] patented an apparatus which upgrades heavy hydrocarbons using radio frequency plasma. It is classified as capacitive coupled plasma ( CCP) and inductively coupled plasma (ICP)³⁰. ICP has played an important role in the realm of elements detection 9 rather than oil processing. This is due to its high sensitivity and the fact that it does not need electrodes. Therefore 9 radio frequency discharge does not be elaborated upon in this paper.
Arc plasma is another principal discharge form, characterized by high electric current density, high luminous intensity and high temperature. Its electric energy can be injected directly into the reactor, providing a plasma environment filled with active particles. More than 80 % of the electric energy converts to thermal energy of gases, which is beneficial to the feedstock with poor flow ability⑶].The plasma torch is also special device established by arc. But, arc is very dangerous. This is due to its strong power, which even gives rise to sudden cardiac arrest. Therefore ? a lot of attention has to be paid when arc is applied.
Microwave plasma is especially applicable to low pressure discharge because it is created using wide pressure range ? from 1 kPa to 0. 1 MPa⑶L
However 9 the microwave power system is rather more complicated than others, causing low efficiency.
Dielectric barrier discharge has been chosen to treat heavy hydrocarbons more often for two main reasons. First, it can produce non-thermal equilibrium plasma, which is more preferable. Second, it has great potential in terms of equipment of an industrial scale. This is due to its advantage of being operated under atmospheric pressure.
In conclusion, each discharge type has its own characteristics and different discharge types get different results. The appropriate way is chosen depending on the feedstock and experiment.
3. 2 Structure of reactors
Parallel plate and coaxial cylinder are two main reactor structures9 which are shown in Fig. 7. Parallel plate reactor usually consists of two parallel silicon plates 9 which requires high purity in order to prevent dielectric breakdown. Corundum is also used to make parallel plate reactors9 but it's not convenient to observe reaction because of its opacity. Coaxial cylinder reactor is more common than parallel plate because it's easier to create the atmosphere that is needed to increase the contact area between the gas and oil.

The reactors of various discharge methods at laboratory scale have been developed in a relatively diverse way. There are enough references to provide models and patterns. So, it's not advised to spend too much time on designing structure of reactors.
But it doesn't mean that people should stop making reactors more efficient or continually improving them. For instance 9 Mohammad et aL 當"enhanced the electrode material of the dielectric barrier discharge (DBD) plasma reactor. They found that, in comparison to other materials 9 like copper, iron, brass and aluminum 9 steel was the most efficient material 9 with the lowest temperature and energy consumption under certain voltages and pulsed frequency.
As most of the research conducted now is based on surface treatment, cylinder reactors are more preferable than parallel-plate reactors 9 for increasing contact area. But all types of reactors face the problem of scale-up. Some fundamental studies have concentrated on pilot-scale or industrial-scale. The next step should focus on scale-up 9 based on optimization of parameters.
3. 3 Voltage and power
Applied voltage also has a close relationship with performance. Studies show that gas production and input power are increasing with the enhancement of voltage.
In our study, the DBD reactor had been used to process diesel and asphalt to find the correlations between voltage and performance. Gas chromatography-mass spectrometry was firstly used when diesel was treated 9 and there is an apparent change of carbon distribution after experiment. Then, gas chromatography results show that a lot of gas products from Ci to C7 are obtained after treatment, and their concentration is increased at higher voltage. The chromatogram and their relations are shown in Fig. 8 and Fig. 9, respectively.
In order to give a basic comparison of these parameters 9 some promising experiment results in the field of plasma assisted reforming systems are shown in Table 2. The conversion rates presented here are optimum ones and they show a wide spread. The highest conversion is achieved by Petrochemical Research and Technology Company with a flow rate of argon to methane of 4000 to 400 mL/min®l.

3.4 Working gases
In general ? working gases that applied to treat heavy hydrocarbons should have two characteristics. First 9 its impingement particles have enough energy to break down the bonds of the heavy hydrocarbons. Second, it contains a high concentration of hydrogen free radical to prevent oxidization reactions when bonds are being broken. Based on these characteristics, hydrogen is considered as the most efficient working gas. However, hydrogen is only used on a laboratory scale due to the lack of an appropriate way to store 9 and its high cost. Therefore 9 some hydrogen-rich gases are chosen to conduct experiments 9 such as methane and ethane. Methane is more difficult to ionize, with a stable molecular structure due to the high bond energy between carbon and hydrogen atoms. As a result, hydrogen-rich gases are always used by mixing them with other noble gases ? such as Argon and Helium, in a certain proportion to lower onset voltage.
Ling et al. 口幻 used air and argon to treat heavy
oil, and results showed that argon was more suitable than air. Then, Li et al. [34_35] studied coal tar conversion and gas product yield under various hydrogen volume percentages. The conclusions point that the coal tar conversion is only 30. 1 % in the absence of hydrogen gas. However, with the increasing in hydrogen volume percentage, the conversion and yield of acetylene are improved significantly. It is inferred that hydrogen plasma provides a reaction system with active particles and higher thermal conductivity. This promotes coal tar to be heated up, gasified and transformed. In contrast, methane has the opposite effect when it is mixed with argon. Taghvaei examined four different volume percentages of methane of 0, 25%, 75% and 100%[36]. The results suggest that onset voltage become increased with being larger percentage of methane, leading to the decrease of gas production and energy efficiency.
Mohammad investigated working gas types and found that the cracking percentage for methane was higher than for air[18]. Therefore, other experiments were conducted by using methane as the working gas. Mahtab et al. [20] suggested that ethane has a better effect than methane under the same conditions. Some experiment data is shown in Table 3. A similar comparison can be found in ref. [17], which indicates that the yield of light hydrocarbons in different working gases follows the order： H2>C2 H6 >CH4>N2.

Table 3 The effect of methane and ethane on gas production[20]
Argon flow/
(mL , min 1) Methane flow/
(mL , min 1) Ethane flow/
(mL , min 1) PFO volume/
mL Applied voltage/ kV Hydrogen yield/
(mL , min 1) Hydrocarbon yield/
(mL , min 1)
3300 0 0 1 10 5. 2 2. 12
3000 300 0 0 10 18. 3 4. 63
3000 300 0 1 10 28. 8 6. 47
3000 0 300 0 10 23. 5 8. 30
3000 0 300 1 10 31. 26 17. 75
PFO一Processed fuel oil

In brief ? choosing the appropriate working gas is an important aspect in further studies. It is closely related to the efficiency of ionizing plasma, conversion and the selectivity of products. A mixture of argon and hydrogen rich gas is suggested to be the priority from the comprehensive perspective of economy and efficiency.
4 Conclusions
Applying plasma in the field of fuel oil processing exhibits great values and promising prospects. Unlike previous technology, plasma is an emerging technology that is simple, green and efficient.
At present, the main direction of plasma treating heavy hydrocarbons is to obtain light olefins and hydrogen. Structure of reactor, power and working gas are the important parameters that play a critical role in the effect of discharge, thus they are worth further research and improvement. The cylinder reactor has more advantages than the parallel-plate reactor. Increasing voltage enhances power and energy density under certain conditions, producing more light products. Argon is usually chosen as the working gas, but its onset voltage is relatively large due to its high metastable energy. Therefore, a mixture of argon and a hydrogen-rich gas, like methane or ethane, is the best choice. If hydrogen-rich gases are made into plasma, they can be used to increase the supply ability of activated hydrogen during the process of heavy oil upgrading. This is not only helpful to overcome the coking problem of fixed bed and poor adaptability of feed, but also obtain many gas products through the reactions of free radicals.
The mechanism of plasma reaction is another developing area of research. It is widely assumed that free radical reactions occur during the process. It involves various reactions of different particles, such as atoms, ions and electrons. The process becomes even more complicated with the increasing of the carbon number of feedstock. Therefore, choosing an appropriate model compound to establish a mature mechanism, by using an isotopic tracer method and emission spectrum, is an important direction in further studies.
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