Open Access
Numéro
Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles
Volume 75, 2020
Numéro d'article 6
Nombre de pages 10
DOI https://doi.org/10.2516/ogst/2019063
Publié en ligne 27 janvier 2020

© A. Ahmadbaygi et al., published by IFP Energies nouvelles, 2020

Licence Creative CommonsThis is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1 Introduction

Asphaltene in heavy crude oil can cause enormous losses in flow rate due to deposition in pipelines and operational equipment as well as obstruction of wells (Berenblyum et al., 2011; Nasralla et al., 2018; Ramirez et al., 2017). Precipitation and deposition of asphaltene have become a crucial problem to almost all petroleum production, processing and transportation facilities (Afra et al., 2018; Ahmadi and Aminshahidy, 2018; Saeedi Dehaghani and Badizad, 2017; Tirjoo et al., 2019a, b). Precipitation and deposition of asphaltene would partially or completely block the pores and change the permeability of the flow paths in reservoirs. Reducing permeability leads to additional pressure drop and consequently an increase in the amount of asphaltene precipitation, and as a result, the pores of the reservoir rock are further blocked. It can also cause to completely obstruct the flow of oil from the outlet of the well (Gharbi et al., 2017; Gonzalez et al., 2017; Loureiro et al., 2015). At initial condition, the operational pressure and temperature are very high, as a result asphaltene is soluble in the mixture of heavy crude oil bitumen and tar, but upon operational conditions changes, asphaltene deposition starts and causes flow problem (Gonzalez et al., 2017). In some cases, gas injections, including injection of CO2, can disturb the chemical and thermodynamic balance of crude oil and cause precipitation of asphaltene. Of course, some key factors such as solvent type sample/precipitant ratio and contact time cannot be ignored in the analysis of the process (David Ting et al., 2013; Ebrahimi et al., 2016; Hammami et al., 2000; Hu and Guo, 2001; Shojaati et al., 2017). Keeping the operational conditions at the level similar to the initial condition is practically impossible and is very difficult and costly work, thus effectual ways should be chosen to solve the problem. Widespread research have been performed in this field, a likely way of avoiding asphaltene precipitation that has been studied and suggested is adding and using asphaltene inhibitor, i.e., stabilizer (Ebrahimi et al., 2016; Gharbi et al., 2017). Pretreatment of chemical inhibitors can prevent precipitation, and enhance product of light oil from raw material. Asphaltene precipitation in heavy crude oil and extra-heavy crude oils is a common phenomenon. Heavy and extra-heavy crude oils have high viscosity, as well as a low API gravity (Choi et al., 2016; Doryani et al., 2018; Ghloum et al., 2010; Ovalles et al., 2016). From the molecular point of view, the asphaltenes are polar aromatic compound that exist in crude oil, which also contains resin, aromatic hydrocarbons and saturated hydrocarbons (SARA) (Bahman et al., 2018; Dehaghani et al., 2018; Doryani et al., 2016; Karambeigi et al., 2016). Asphaltene molecules are soluble in alkene but insoluble in normal alkanes (Melendez-Alvarez et al., 2016; Rogel and Moir, 2017; Sayyad Amin et al., 2017; Wang and Buckley, 2001). From the macroscopic view point, the asphaltene is composed of polyaromatic core, which are captured by aliphatic chain (Chávez-Miyauchi et al., 2013; Javanbakht et al., 2018; Mena-Cervantes et al., 2013; Mousavi-Dehghani et al., 2004; Ramirez et al., 2017; Wiehe et al., 2005). Asphaltene has high level of sulfur, nitrogen, and heavy metals (such as Ni, V, Fe) and the average ratio of hydrogen to carbon atom (H:C) in asphaltene is 1:1.2 (Al-Sahhaf et al., 2002; Escobedo and Mansoori, 1995; Gonzalez et al., 2017; Javanbakht et al., 2018; Lu et al., 2008). Due to aggregation of maltene molecules in solution, it is not possible to characterize the mean molecular weight of asphaltene in crude oil.

When asphaltene molecules are separated from the oil phase form a unique phase. Asphaltene which their sizes are bigger than 500 nm become to precipitate (Hammami et al., 2000; Ramirez et al., 2017).

It should be borne in mind that asphaltene is stable due to the presence of resin in crude oil with polar groups and less molecular weight (Al-Sahhaf et al., 2002; Escobedo and Mansoori, 1995; Lu et al., 2008; Honse et al., 2012). Thus, to reduce the amount of asphaltene deposition, it is necessary to use a surfactant that had similar compounds with resin and diverse in the polar heads and a polar tails. Most of the costs are related to the production of raw materials for inhibitors. Therefore, asphaltene inhibitor should be selected with the optimum concentration (Imanbayev et al., 2017; Mao et al., 2017; Permanyer et al., 2002; Shojaati et al., 2017; Simakov et al., 2015; Smith et al., 2008). Recently researchers have shown that asphaltene acts as a weakly hydrous binder and also as a strong receiver of hydrous bands, which shows that asphaltene is a Lewis base. Therefore, surfactants with a Lewis acidic structure can be used as an inhibitor of asphaltene precipitation (Bahman et al., 2018). Except asphaltene, other components that exist in crude oil are called maltene, which are extracted by chromatography column (Wang and Buckley, 2001). Efficiency of asphaltene inhibitors depends on the chemical structure of inhibitors and the amount of resin, aromatic and other component that exist in asphaltene inhibitors and the amount of acidity of asphaltene inhibitor. The structure of asphaltene in crude oil is also very important to be chosen the asphaltene inhibitor with the highest efficiency. In more cases, asphaltene inhibitors that contain higher amount of resin rather than other component, have a more effect on prevention of asphaltene precipitation. It should be borne in mind that the addition of inhibitors does not always have a positive effect, and even in some cases it has a neutral and possibly negative effect. Always adding high amount of inhibitor does not have high efficiency in preventing asphaltene precipitation, therefore it is necessary to determine the optimum amount of asphaltene inhibitor. Melendez-Alvarez et al. have shown that other factors such as the type and amount of solvent, the temperature and the operating pressure are the effective parameters on inhibitory performance for reducing the amount of precipitated asphaltene (Melendez-Alvarez et al., 2016).

Ghloum et al. (2010) studied the effect of different inhibitors on asphaltene precipitation for Marrat Kuwaiti reservoirs. In that research, three commercial and four non-commercial asphaltene inhibitors have been used to determine the Asphaltene Onset Point (AOP), which is the point where asphaltene in crude oil begins to precipitate, using a Solid Detection System (SDS). In this research the effects of the H:C ratio on AOP was also studied. For a ratio of H:C more than 0.8, AOP increases dramatically, suggesting that there is a higher content of hydrogen and a lower amount of carbon in the crude oil, causes AOP to occur at higher volume of n-paraffin. The effect of different asphaltene inhibitors on the amount of asphaltene precipitated has also been studied using the screening test. The results show that in most cases, the amount of asphaltene precipitation has further decreased when inhibitor is used with the highest resin content. It should be borne in mind that, regards to the crude oil structure, asphaltene inhibitor with a higher amount of aromatic (greater polarity), works more efficiently.

In the recent years, a viscometry method has been introduced to investigate the AOP, as well as various inhibitory effects on AOP. In this regard, Saeedi Dehaghani and Badizad (2017) examined this method on crude oil extracted from Iranian oil fields. In this method, they first synthesized synthetic oil and then added different volumes of n-paraffin. The point where the viscosity of the mixture of synthetic oil/n-paraffin system has dramatically changed is determined as the AOP. In their research, four different inhibitors have been used to postpone AOP. Their results showed that the CDEA acts more effectively than the other inhibitors to increase the AOP due to the presence of more polar groups (Saeedi Dehaghani and Badizad, 2017).

To investigate the effect of partial asphaltene phosphorexylated on the decrease of asphaltene precipitation rate, Ovalles et al. conducted research using ASTM D-6560 method (IP-143-test). The results obtained from their study indicate that asphaltene precipitation rate has significantly decreased because of the formation of Aryl-O–P and P=O bands which is due to the addition of partial asphaltene phosphorexylated. Of course, it should be taken into account that, at temperature of 195 °C and the asphaltene phosphorexylated concentration of 100 ppm, the percentage of reduction of asphaltene is as high as possible (percentage of reduction of asphaltene = 42%).

In general cases, different methods such as SDS, Ultraviolet spectrometry (UV test), filtration, viscometry and IP-143 test, are used to study the effect of various inhibitors on the amount of asphaltene precipitated (Doryani et al., 2016; Gonzalez et al., 2017).

In this work, IP-143 test and the spectrometry method have been used to investigate the effect of different inhibitors on precipitated asphaltene content and using Fourier-Transform Infrared (FT-IR) Spectroscopy test and then the obtained results were analyzed. Also, due to the fact that two methods used in this study were carried out at different temperature conditions, the effect of temperature on different inhibitory activity can also be evaluated. The spectrometry method is considered as a faster and better method than other methods of studying the effect of asphaltene inhibitors. The spectrometry method was used to determine the AOP.

2 Experimental

2.1 Materials and methods

2.1.1 Materials

In this research, we used a crude oil from an Iranian oil field in west of Iran, n-heptane and n-hexane (Merc©, purity of 99%) and toluene (Merc, purity of 99%). Three inhibitors A, B, and C also have been used to reduce the amount of asphaltene precipitation.

2.1.2 Methods

2.1.2.1 Extraction of asphaltene

The IP-143 method (Sayyad Amin et al., 2017) was applied for the determination of crude oil asphaltene content. Two n-paraffins and toluene were used for precipitation and purification of asphaltene, respectively. First, 2.5 g of crude oil weighted and mixed with 100 g of n-heptane (ratio:401=n-paraffinscrude oil)$ \left(\mathrm{ratio}:\frac{40}{1}=\frac{n-\mathrm{paraffins}}{\mathrm{crude}\enspace \mathrm{oil}}\right)$. The first reflux was performed for asphaltene precipitation in crude oil by the n-paraffins solvent in the Soxhlet extractor. The primary reflux was done for 1.5 h, then n-paraffins/crude oil solution was aged overnight in dark place. In the second stage, the obtained mixture was filtered using filter paper. The asphaltene and small amount of other components were deposited on the filter paper. The second reflux has been done for separating other components that were bonded in the filter paper by adding n-paraffins. In the last reflux, the sliced asphaltene into the filter paper was separated by adding toluene. Finally, the asphaltene-toluene solution put under a slow stream of air to evaporate the toluene.

In this section, two kinds of normal paraffin, n-Hexane and n-Heptane have been used to study the effect of paraffin chain length on asphaltene precipitation.

2.1.2.2 Synthetic oil synthesis

Synthetic oil was prepared in order to determine AOP and investigate the effect of different asphaltene inhibitors. For this purpose, a certain amount of asphaltene was added to the toluene solvent. To obtain a uniform solution, the resulting mixture was stirred for 5 h.

2.1.2.3 Determination of AOP

To determine AOP, different volumetric percentages of n-paraffins were added to synthetic oil. In order to completely disrupt, the synthetic oil/n-paraffin mixture was centrifuged at 3000 rpm for 15 min.

To determine the absorbance of each sample, 1 cc of the upper part of the mixture was removed and mixed with 10 cc of toluene. The absorbance values were plotted as a function of nC7 volume fraction. The rapid deviation from linear trend in the data points corresponds to the nC7 volume fraction at the onset point.

2.1.2.4 Asphaltene inhibitor test

Two methods have been used to study the effect of adding different inhibitors on the asphaltene precipitation. In the first method, spectrometry was used to evaluate the effect of asphaltene inhibitor on the amount of asphaltene precipitation at different percentages of n-paraffin. The samples with a different ratio of the n-paraffin/synthetic oil were mixed at ambient temperature for 1.5 h, then the solution was centrifuged at 3000 rpm for 15 min. To investigate the effect of inhibitors, a fixed amount of inhibitor was mixed with the synthetic oil/n-paraffin solution, and was stirred at ambient temperature. The absorbance value for each of sample is determined at specified wavenumber using a UV spectrometer.

In the second method, the effect of adding various amounts of different inhibitors on the amount of asphaltene precipitated was investigated using the IP-143 standard test. The weighed crude oil samples were mixed with identified amounts of inhibitor, and then placed under the shaking for several minutes to complete mixing.

Then, as mentioned above, the amount of asphaltene present in crude oil was achieved by adding different volume percentage of normal paraffin as a precipitating agent and toluene as an asphaltene solvent and was refluxed several time.

3 Characterization

The elemental analysis of the extracted asphaltene of crude oil sample was carried out using a COSTECH-4010 model analyzer (CHNSO analyzer). FTIR (Bruker-VERTEX 70 model analyzer) was used to structural characterization of asphaltenes. UV–Vis spectrophotometry (Cary 100 model) was used to find the concentration of an asphaltene in different samples solution. Quantitative proton H and carbon C NMR spectroscopy analyses were performed using a Nuclear Magnetic Resonance (NMR) BRUKER spectrometer operating at 500 MHz. Chloroform was used to dissolve the extracted asphaltene sample.

4 Results and discussion

4.1 Properties of asphaltene

To determine weight percent of component that exist in asphaltene, elemental analysis were used, which obtained results from this analysis were presented in Table 1. As it can be seen, the asphaltene content in the crude oil sample has higher carbon atoms than the other ones.

Table 1

Elemental analysis for pure asphaltene extracted from the Iranian oil field.

The H:C ratio of asphaltene in the crude oil sample is 0.983. Since molecular weight of H and C are 1 and 12, respectively, and according to the weight percentages obtained from the CHNSO test, the molar ratio of H:C is equal to 0.98294. Ghloum et al. (2010) showed that asphaltene in crude oil is more unstable if the H:C ratio is less than 0.8, therefore, AOP occurs in smaller amount of n-paraffin. In the other hand, if the H:C ratio is more than 0.8, more volume of n-paraffin is needed to observe AOP. Thus, due to the H:C ratio of the crude oil asphaltene, it is anticipated that AOP will be appeared at a high volume of n-paraffin.

The complex and rich nature of this asphaltene was studied by NMR spectra. To receive a useful information, it requires systematic approach, so as to identify/quantity the molecular nature from these spectra. For H NMR spectra contributed by protons, the aromatic peaks are well resolved (6.5–9.5 ppm) from the aliphatic ones (0.5–4.5 ppm) and the spectra are more reliable. The aliphatic peaks are further divided into three types of protons (a, b and c).

The peaks at 0.5–1.0, 1.0–1.85 and 1.85–4.5 ppm are related to a, b and protons, respectively. These borders are approximate because the effect of hetero atoms and metals on peak shifting is neglected. Figure 1 shows the H NMR spectrum. It clearly shows an aromatic region and a large aliphatic domain. The aromatic:aliphatic hydrocarbon ratio is 1:7.6 and aromatic:aliphatic carbon ratio is 1:1.7758.

thumbnail Fig. 1

NMR spectrum of the extracted asphaltene from the crude oil.

4.2 Properties of asphaltene inhibitors

Three different inhibitors have been used in this study. The density and pH of inhibitors were presented in Table 2. As shown in Table 2, B inhibitor has a more density and acidity than other inhibitors. This inhibitor has higher acidic potency than the other two inhibitors, so it can be concluded that inhibitor B consists of greater amounts of hydrogen groups and other polar groups than both inhibitors A and C. The higher the polarity of the inhibitory constituents, the greater the effect of combining the inhibitor with the polar portion of the asphaltenes, and the polar–polar bonding between the inhibitor and the asphaltenes creates a protective layer around the asphaltenes, causing non-asphaltene-induced invasion. Protect the presence of normal paraffin and prevent excessive deposition of asphaltene. Inhibitors A and C have lower acidic strength due to their constitutive structure.

Table 2

Density and pH of three different asphaltene inhibitors.

FT-IR spectrum results of the asphaltene inhibitors of A, B and C, are shown in Figures 24, respectively.

thumbnail Fig. 2

The FT-IR spectrum of the asphaltene inhibitor A.

The FT-IR spectrum of the asphaltene inhibitor A was represented in Figure 2. As shown in this figure, there is a high intensity tensile N–H band in the wave number of 3433 cm−1, which act as a factor in creating polarity and acidity of asphaltene inhibitor A. There is a flexural N–H band in the wavenumber of 1639 cm−1, which has a similar function to tensile N–H band. There is also a weak non-polar band in this asphaltene inhibitor. During the wavenumber of 2854 and 2925 cm−1, C–H bands are appeared. There are non-polar bands that are related to the C=C band at wavenumber of 1348 and 1468 cm−1.

As the FT-IR spectrum is related to asphaltene inhibitor A, the polar bands intensity of the asphaltene inhibitor A is more severe than non-polar bands, which is due to the acidic and polarizing factor of this kind of asphaltene inhibitor (A type).

As shown in Table 2, the asphaltene inhibitor B has a density of 0.976 kg/m3, indicating that the asphaltene inhibitor B has a high concentration. Therefore, in order to completely mix of this asphaltene inhibitor with the reference material (the material that should be mixed the sample to FT-IR test), asphaltene inhibitor B must be diluted with a small amount of n-heptane. As can be seen from Figure 3, the intensity of non-polar bands in the asphaltene inhibitor B is high. It can be due to the mixing of this inhibitor with n-heptane and the presence of non-polar bands in n-heptane.

thumbnail Fig. 3

The FT-IR spectrum of asphaltene inhibitor B.

For the asphaltene inhibitor B, the tensile and flexural bands were appeared at wavenumber of 3434 and 1601 cm−1, respectively. The acidic and polar nature of the asphaltene inhibitor B is due to the likely N–H bands.

Figure 4 is the FT-IR spectrum for the asphaltene inhibitor C. In the wavenumber of 2926 and 2853 cm−1, there is P–CH3 that acts as an acidic agent. Also, the binary C=O band appears in the wavenumber of 1738 cm−1, which also arising from the polarity and acidity of C inhibitor.

thumbnail Fig. 4

The FT-IR spectrum of the asphaltene inhibitor C.

4.3 The effect of two n-paraffins on asphaltene precipitation

In this work, n-Hexane and n-Heptane have been used to extract asphaltene in the crude oil. In each sample, crude oil was mixed with n-Hexane or n-Heptane for initial reflux and precipitation of asphaltene in crude oil (n-Hexane or n-Heptane crude oil=401)$ \left(\frac{n-\mathrm{Hexane}\enspace \mathrm{or}\enspace {n}-\mathrm{Heptane}\enspace }{\mathrm{crude}\enspace \mathrm{oil}}=\frac{40}{1}\right)$. Other stages of asphaltene extraction were the same as the procedure, which was described in the previous section.

0.0753 g of pure asphaltene was obtained when n-Hexane was used as asphaltene precipitant. Considering the crude oil density (0.837 g/cc), the crude oil contained 3 wt.% asphaltenes. However, there was 0.0141 g asphaltene in oil sample. Since heptane has more carbon atoms, it has a higher non-polar power. Therefore, n-Heptane can extract more asphaltene by interaction with non-polar region of asphaltene. Wiehe (2012) also stated that the solubility parameter of n-Heptane is higher than solubility parameter of n-Hexane, so that the amount of asphaltene precipitated by n-Heptane was higher than the amount of asphaltene precipitated by n-Hexane.

4.4 Investigation the effect of inhibitors using IP-143 test

The effect of asphaltene inhibitor on the asphaltene precipitation was calculated using equation (1):

Asphaltene reduction (%)=Asphaltene content without inhibitor-Asphaltene content with inhibitorAsphaltene content without inhibitor×100.$$ \mathrm{Asphaltene}\enspace \mathrm{reduction}\enspace (\%)=\frac{\mathrm{Asphaltene}\enspace \mathrm{content}\enspace \mathrm{without}\enspace \mathrm{inhibitor}-\mathrm{Asphaltene}\enspace \mathrm{content}\enspace \mathrm{with}\enspace \mathrm{inhibitor}}{\mathrm{Asphaltene}\enspace \mathrm{content}\enspace \mathrm{without}\enspace \mathrm{inhibitor}}\times 100. $$(1)

0.042 g of asphaltene was obtained by IP-143 method without using asphaltene inhibitor, which is considered as the basis for examining the effect of the adding different amounts of asphaltene inhibitors. However, by adding 500 ppm of asphaltene inhibitor A to crude oil, asphaltene precipitation was reduced to 0.025 g. Based on equation (1), the decreasing of asphaltene precipitation was 40.47 wt.% when 10 000 ppm of asphaltene inhibitor A was added to the crude oil, the conditions were quite different from the previous one. In this case, 0.46 g of asphaltene was obtained. Thus, the asphaltene precipitation has been increased 9 wt.% alternatively, by adding 10 000 ppm of asphaltene inhibitor A to the crude oil, the obtained results were unexpectable, and the amount of asphaltene precipitated was increased compared to the case without the asphaltene inhibitor. The results suggest that always adding asphaltene inhibitor does not necessarily reduce the amount of asphaltene precipitation. The effect of A inhibitor on the extracted asphaltene obtained by IP-143 method were presented in Table 3.

Table 3

Effect of various quantities of A inhibitor on the amount of asphaltene extracted from the crude oil.

Mentioned tests have also been carried out on inhibitor B. The obtained results are shown in Table 4. As can be seen from this table, the increase in inhibitor B is associated with a decrease in the amount of asphaltene precipitated. When 3000 ppm of asphaltene inhibitor B was added to crude oil, the amount of asphaltene extracted was 0.031 g. Based on equation (1), asphaltene precipitation was reduced 26.19 wt.% but when 10 000 ppm of asphaltene inhibitor B was added into the crude oil, this amount decrease to 0.0286 g. Therefore, from the economic perspective, the concentration of 3000 ppm from inhibitor B has the highest inhibitory effect (compared to the other concentration of asphaltene inhibitor B).

Table 4

Effect of various quantities of B inhibitor on the amount of asphaltene extracted from the crude oil.

According to the results obtained from the IP-143 test, it can be seen that asphaltene inhibitor A has higher efficiency at same concentrations of A, B inhibitors.

It is important to note that the IP-143 method was performed at a higher temperature than the spectrometry method, as well as the asphaltene precipitation time in the IP-143 method is greater than the time of asphaltene precipitation in spectrometry method. Therefore, a contradiction in the results obtained from these two methods was observed which indicates that asphaltene inhibitor A is more effective on the asphaltene precipitated in IP-143 method.

4.5 Investigation of the effect of inhibitors using spectrometry method

In order to investigate the effect of three different asphaltene inhibitors on the amount of asphaltene precipitation using spectrometry method, synthetic oil was prepared with concentration of 0.5 wt.% from asphaltene were mixed with ratio of 1:1 of oil:n-heptane (n-Heptane 50 vol.%). The results were shown in Table 5.

Table 5

Amount of absorbance for mixture of synthetic oil/nC7 with different concentration of inhibitors.

The results obtained from spectrometry method (see Tab. 5) show that A and C inhibitors have the same inhibitory effect, although asphaltene inhibitor A at lower concentration is more effective which indicates that the asphaltene inhibitor A economically is better. As it is evident, asphaltene inhibitor B has a greater absorbance number than A and C inhibitors. It is noteworthy that the greater inhibitory power is available to inhibitor B at high concentrations of this inhibitor.

The higher inhibitory effect were occurred at 500, 3000 and 500 ppm of A, B, and C inhibitors, respectively. The results obtained from the spectrometry method indicated that asphaltene inhibitor B has a higher inhibitory effect (at higher concentrations), however, from the economic point of view and in order to find an optimal concentration, asphaltene inhibitor A is the most acceptable one than B and C inhibitors. Therefore, the concentration of 500 ppm of asphaltene inhibitors A considered as the optimal concentration (from the economic point of view), but in terms of inhibitory power, the asphaltene inhibitor B with a concentration of 3000 ppm has the highest efficiency.

4.6 Determination of the AOP using spectrometry method

In this research, AOP was determined using spectrometry method. Further, various volumetric percentage of n-heptane were added to synthetic oil. Asphaltene precipitation was performed for 1.5 h at ambient conditions, then the mixture was centrifuged in a time of 15 min and at a rate of 3000 rpm, the absorbance number were determined at specified wavenumbers. The point at which the number of absorbance was defeated is known as AOP.

The AOP in the presence of optimal values from three different asphaltene inhibitors and without asphaltene inhibitors were shown in Figure 5.

thumbnail Fig. 5

Absorbance of synthetic oil as function of n-heptane vol.% in presence of different inhibitor.

As it is shown in this Table 5, without asphaltene inhibitor, the absorbance number reached a constant amount at 35 vol.% of n-heptane, which is introduced as AOP.

The absorbance number reached a constant amount in 52.5 vol.% of n-heptane, when the amount of 500 ppm of inhibitor A was added to the mixture. As a result of adding optimal amounts of B and C inhibitors, AOPs were occurred at 60 and 50 vol.% of n-heptane, respectively. It can be seen from Table 4 that at ambient temperature and pressure, in the presence of asphaltene inhibitor B, AOP was occurred at a larger volume of n-heptane, which indicates that this inhibitor is more effective in increasing the AOP. Due to the fact that the spectrometry method is carried out at ambient temperature and the IP-143 method is used at the boiling temperature of the mixture of normal paraffin and crude oil, the inhibitor performance varies in different temperature conditions. If the inhibitor is to be used in downstream industries where the temperature of the crude oil is nearer to the ambient temperature, the inhibitor A is better, if the inhibitor is to be injected at a higher operating temperature (inside the crude oil well), the inhibitor B have a higher efficiency.

4.7 FTIR analysis of various inhibitory effect

FTIR spectrums for asphaltene were obtained from the IP-143 in the presence of different amount of acidic inhibitors were shown in Figure 6. As it can be seen from this figure, by adding asphaltene inhibitor A, the tensile and flexure bonding of N–H were appeared with different intensities in the FTIR spectrum of asphaltene. As previously described, asphaltene is a dense aromatically ring with alkyl side chain and polarizing functional groups which is maintained in the crude oil solution by resin. Therefore, polar bands, such as tensile and flexure N–H and O–H, can keep the asphaltene in the solution and prevent them to precipitate.

thumbnail Fig. 6

The variation of the FT-IR spectrum for the asphaltene extracted in the presence of different amounts of the inhibitor A (the green, brown, purple and red spectra are related to concentration of 0, 500, 4200 and 10 000 ppm of inhibitor A, respectively).

The pigments of the tensile and flexure were appeared at the wave number of 3467 and 1634 cm−1, respectively, when the amount of 500 ppm of the asphaltene inhibitor A was added to the crude oil. The mentioned pigments were not exist in the asphaltene without chemical inhibitor. It can also be seen that the tensile and flexural of N–H pigments, for 500 ppm of asphaltene inhibitor added, has the highest severity. When 4200 ppm of inhibitor A was added to the crude oil, the tensile and flexural pigments were appeared at 3468 and 1645 wavelengths, which are less than sample with 500 ppm of asphaltene inhibitor. This difference in the intensity of the N–H bands changes the amount of asphaltene obtained from the IP-143 method. By adding 10 000 ppm of the asphaltene inhibitor A, the FTIR spectrum was different from the other samples. As shown in Figure 6, the picks of N–H flexure in 3468 cm−1 wavelength is considerably reduced, which could be one of the main reasons for the increased of asphaltene extracted from the crude oil by adding 10 000 ppm of asphaltene inhibitor A. The pigtails of the C=C double band was also appeared at the 1400 cm−1 wave number. The C=C dual band is a strong non-polar band that can be linked to a non-polar–non-polar bond with asphaltene. Hence, n-paraffin can be more easily linked to non-polar part of the asphaltene, which were potentiated by adding up to 10 000 ppm of asphaltene inhibitor. Hence, asphaltene precipitation was increased.

The FT-IR spectrum for the extracted asphaltene from the crude oil for the cases in which the amount of 1000, 2000 and 3000 ppm of asphaltene inhibitor B were added to the crude oil, respectively, are shown in Figure 7. In this figure, new pigments appear in the FTIR spectrum of the extracted asphaltene for the case that 3000 ppm of asphaltene inhibitor B (the concentration, which shows the highest inhibitory effect for asphaltene inhibitor B), were added to crude oil. In the wavenumber of 3051 cm−1 a double carbon bonding was appeared, causing a greater amount of asphaltene precipitation, while in wavenumber of 3440 cm−1, a slightly tensile N–H was formed, which reduces the asphaltene precipitation. In the wavenumber of 2953–2921 cm−1, the bands belong the aliphatic group (CH3), which increases the non-polar behavior and consequently increases the asphaltene precipitation. In the wavenumber of 1136 cm−1, an acidic C–O bond was also appeared. This C–O bond reduces the amount of precipitated asphaltene and increases the absorbance number of UV test. In general, by adding 3000 ppm of asphaltene inhibitor B, due to the high contrast between polar and non-polar bonds, the percentage of the reduced asphaltene was not as considerable as expected. Nevertheless, due to polar bonds being overcome by non-polar bonds, adding this amount from asphaltene inhibitor B showed a positive effect on asphaltene precipitation.

thumbnail Fig. 7

The variation of the FT-IR spectrum for the asphaltene extracted in the presence of different amounts of the inhibitor B (the blue, red and green spectra are related to concentration of 1000, 2000 and 3000 ppm of inhibitor B, respectively).

According to Figure 7, by adding 1000 and 2000 ppm of asphaltene inhibitor B, the intensity of the N–H and C–O bands for the extracted asphaltene decreases, which causes a decrease in the asphaltene polarization, therefore, the extracted asphaltene was increased rather than the case that 3000 ppm of asphaltene inhibitor B was added to the crude oil.

As a general conclusion of the results of the FTIR spectrums, at high temperatures, asphaltene inhibitor A forms stronger polar bands than asphaltene inhibitor B.

Asphaltene acts like Lewis base, therefore it interacts well with the inhibitor, which plays as a Lewis acid. Considering that pH for A, B and C asphaltene inhibitors are 3.8, 2.8 and 5.3 respectively, it can be concluded that the acidic properties of these inhibitors result in the stability of asphaltene in crude oil. Also, because asphaltene acts as a strong receiver of a hydrous band and a poor supply of hydrous bands, the transfer of the hydroxide band from acidic inhibitors to asphaltene causes its stabilization in crude oil.

5 Conclusion

In this research, the effect of three different asphaltene inhibitor on reduction of asphaltene precipitation by two different methods such as IP143 and spectrometry methods have been investigated. AOP was also determined by spectrometry method. The following conclusions were obtained from this research, which confirms that Asphaltenes would act as Lewis base: The inhibitors that have acidic and polar portions, play a role in the formation of resin as a result of the formation of bond with the polar regions of asphaltene, which reduces the asphaltene deposited in the crude oil due to the presence of normal paraffin. In addition to reducing the amount of asphaltene sedimentation, chemical inhibitors also cause the AOP to be dropped. The experimental results show that temperature condition is a key factor on the performance of different inhibitors on decreasing asphaltene precipitation.

Acknowledgments

The authors would like to thank Ilam University and Iranian Central Oil Company for the financial support of this work. Also, thank co-workers and technical staff in the chemical engineering department.

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All Tables

Table 1

Elemental analysis for pure asphaltene extracted from the Iranian oil field.

Table 2

Density and pH of three different asphaltene inhibitors.

Table 3

Effect of various quantities of A inhibitor on the amount of asphaltene extracted from the crude oil.

Table 4

Effect of various quantities of B inhibitor on the amount of asphaltene extracted from the crude oil.

Table 5

Amount of absorbance for mixture of synthetic oil/nC7 with different concentration of inhibitors.

All Figures

thumbnail Fig. 1

NMR spectrum of the extracted asphaltene from the crude oil.

In the text
thumbnail Fig. 2

The FT-IR spectrum of the asphaltene inhibitor A.

In the text
thumbnail Fig. 3

The FT-IR spectrum of asphaltene inhibitor B.

In the text
thumbnail Fig. 4

The FT-IR spectrum of the asphaltene inhibitor C.

In the text
thumbnail Fig. 5

Absorbance of synthetic oil as function of n-heptane vol.% in presence of different inhibitor.

In the text
thumbnail Fig. 6

The variation of the FT-IR spectrum for the asphaltene extracted in the presence of different amounts of the inhibitor A (the green, brown, purple and red spectra are related to concentration of 0, 500, 4200 and 10 000 ppm of inhibitor A, respectively).

In the text
thumbnail Fig. 7

The variation of the FT-IR spectrum for the asphaltene extracted in the presence of different amounts of the inhibitor B (the blue, red and green spectra are related to concentration of 1000, 2000 and 3000 ppm of inhibitor B, respectively).

In the text

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