Modified sulfonated asphalt particles have a bright application prospect of the profile control of thick reservoirs due to the low cost, extensive sources, and good compatibility with reservoir. Nevertheless, the matching relationship between asphalt particles and reservoir pore has seldom been investigated till now. Oversized particles always block the near-wellbore area, which causes high injection pressures, while undersized particles cannot plug large pores. We designed a core for this experiment which has a high permeability zone in front of it and many pressure measuring points. We could quantitatively assess the matching relationship by measuring the on-way resistance coefficient, residual resistance factor, and relative change of permeability of man-made cores after injecting asphalt. Experimental results indicate that asphalt particles with sizes of 0.02 mm, 0.02–0.06 mm, and 0.08–0.1 mm match with reservoir permeability of 500 mD, 1000 mD, and 2000 mD, respectively. Undersized or oversized particles can reduce the conformance control effect, and the concentration of asphalt particles in the injectant can limit their migration ability. When the concentration of asphalt particles increases to 3000 mg/L, accumulations of asphalt particles can be caused in the formation, in which a scheme with asphalt particles alternative water injection is proposed to avoid the accumulation.
Lamadian Oilfield which is a mature thick positive rhythm reservoir in Daqing, coupled with the presence of low permeability intervals, is especially heterogeneous in vertical direction [
Researchers have developed various methods to solve the aforementioned problem, among which profile control is an efficient and widely used one [
In the experiment, the sulfonated modified asphalt is composed of four parts, which are saturated, aromatic, colloid, and asphaltene with SBS polymer and light calcium carbonate added at the same time. After modification, the modified process gives the priority to the physical modification. Its chemical structure unit did not change. When the polymer is added to the modified agent, the swelling and adsorption of the polymer modified agent can change the structure of the asphalt colloid and enhance the gel property of the asphalt. And three-dimensional network structures which are formed by the polymer molecules hinder the drop of a ball. So, the modified asphalt shows relative high suspension ability and also improves the stability under the high and low temperature. Therefore, when the injection pressure reaches a certain degree, the plugging agent can pass through the near-wellbore area of high permeability channels of the target layer for deep profile control. Those agents can improve the reservoir injection profile and swept volume of injected fluid.
Unfortunately, former researches have not solved these problems. First of all, most displacement experiments are conducted in sand pack models, which greatly affects the accuracy of the experimental results due to the large difference between sand pack models and the actual reservoir; secondly, some researchers used man-made cores to conduct the displacement experiment, which guarantees higher similarity to the actual reservoir, but asphalt particles often block the injection end and cannot enter the cores successfully which result in higher injection pressure and reduction of produced liquid. Therefore, the epoxy resin casting cores used in experiment have been improved. In order to avoid the blocking in the injection end, we add a high permeable section on the forepart of cores. The last and more important point is that no one has systematically studied the matching relationship of asphalt grain sizes and reservoir pore sizes until now. As Oversized particles block the injection end and undersized particles are incapable of blocking big pores, the matching relationship of asphalt particle sizes and target pore sizes determines the success of profile control. Therefore, we designed a new fluid drive unit to assess the matching relationship of asphalt particle sizes with pore sizes by measuring the on-way resistance coefficient, residual resistance factor, and relative change of permeability in man-made cores after injecting asphalt [
The reservoir temperature of Lamadian Oilfield in Daqing is 45°C. So the experimental process is carried out under the condition of reservoir temperature.
Injection pressure and flooding efficiency are judged by the compatibility of injection system and the reservoir. If the compatibility is bad, the injected fluid will jam in the pore and increase the injection pressure rapidly. As a consequence of this, the injected fluid cannot reach the target layer and achieve its aims. The realization about compatibility is based on the research on the compatibility of polymer and reservoir. Polymer is a kind of flexible group with certain feature sizes. Its size decides the compatibility of reservoir and polymer. So it can be an essential basis for polymer selection.
The compatibility of asphalt is differing from that of polymer because asphalt particles are a kind of rigid particles and the sizes vary in range. We cannot establish a direct relation between the sizes of particles and the pores’ sizes. We can establish the relation by experiment. The compatibility of asphalt particles means the relation of particle sizes and the permeability of reservoirs. The appropriate particles have good performance on sealing the target layer and migration performance. The migration performance can be evaluated by the resistance coefficient in the different parts of the reservoir and the sealing performance can be evaluated by residual resistance factors and relative change of permeability.
We inject the profile control system in a speed of 1 mL/min and inject 1.5 PV totally. We observed that the injection pressure increases with the volume. We measure the residual resistance coefficient and plugging efficiency by the data about injection pressure.
Among them, the resistant coefficient is an important index to define the ability of controlling asphalt particle mobility; namely, the ability of asphalt particles reduces the mobility ratio, defined as the ratio of water’s mobility to the asphalt particles solution’s mobility:
Residual resistance coefficient (
Relative change of permeability refers to the reduction of water phase permeability’s percentage after the injection of asphalt percentage, whose expression is as follows:
In the formula above,
The diagram of experimental device is shown in Figure
Experimental flow diagram.
Piston vessel with blender.
Compared to sand pack models, man-made cuboid cores that we used in the experiments are of much higher similarity to the actual reservoir. The cores are enfolded by epoxy resin and are capable of bearing a maximum pressure of 1 MPa. To avoid blocking cores’ injection end by asphalt particles, we added a high permeability segment in each core, dispersing asphalt particles and ensuring that the asphalt micro-emulsion enters the cores easily, as shown in Figure
Asphalt particles of different grain sizes.
Apart from those aforementioned modules, the other experimental equipment does not change. A constant-flux pump is used for constant speed displacement or variable speed displacement, compressing fluid to flow in porous media. Its displacement velocity range is between 0.1 mL/h and 600 mL/h and the control accuracy is 0.01 mL/h. The thermostat we used has a control accuracy of ±1°C, building an experimental environment equal to the actual reservoir temperature, obtaining the transformation effect of asphalt particles. We also used three kinds of pressure sensors: low range pressure sensor DP130-26, with a measuring range of 3.5 KPa; medium range pressure sensor DT15-TL, with a measuring range of 35.0 KPa; high range pressure sensor DT15-TL, with a measuring range of 140 KPa. By connecting the sensors to a computer, we detected and collected the pressure data.
The water used in the experiments is on-site injection water. Its salinity composition is shown in Table
Water salinity composition.
Dilution water (mg/L) | Cl− |
|
|
|
K+ + Na+ | Ca2+ | Mg2+ | Total salinity |
---|---|---|---|---|---|---|---|---|
Fresh water | 54.79 | 31.41 | 236.61 | 15.51 | 68.92 | 41.50 | 18.55 | 467.28 |
The asphalt we used mainly consists of saturates, aromatics, colloid, and asphaltene, where the content of colloid and asphaltene is 77.5%, with SBS polymer and light calcium carbonate added. To get experimental asphalt particles, the asphalt is further prepared by oxidization, sulfonation, and cooling grind. Taking the permeability range of the actual reservoir into consideration, asphalt particles of 5 grain sizes are prepared: 0.02 mm, 0.02–0.06 mm, 0.06–0.08 mm, 0.08–0.1 mm, and 0.1–0.3 mm, as shown in Figure
The cores used in the experiments are man-made cuboid cores enfolded by epoxy resin. Their macroscopic permeability, porosity, and micro-pore structure are highly similar to the actual reservoir. The size of each core is 300 × 45 × 45 mm with a high permeability segment at one end to disperse asphalt particles (as mentioned in the last paragraph in Introduction). To measure the on-way pressure after injecting asphalt micro-emulsion, we uniformly set 4 pressure sensors along the core, as shown in Figure
Diagram of man-made core and pressure sensors.
The main procedure of the experiment is as follows. Detailed process is illustrated in Figure Measure the size of man-made cores. Weigh them, in preparation for calculating pore volume and porosity. Vacuumize the core and saturate the formation water, measure the core permeability by water, and calculate the porosity. Measure the core’s permeability with water. Inject the profile control system constantly. The total injection quantity is 1.5 PV. Record the change of the pressure and the rate of flow. Water floods after injecting asphalt until the pressure difference at both ends of the core reaches stability again.
Asphalt particle profile control is a method which can seal the high permeability area in the layer on the benefit of particle mechanical blockage effect. This method can expand swept volume and improve ultimate recovery. In addition, asphalt particles will cement with each other at high temperatures. The size of molecular thread becomes bigger, which is beneficial to seal the core pores. At the same time, the asphalt coil adheres to the core framework. This process will produce two kinds of forces. Before injecting asphalt micro-emulsion, we have an anionic surfactant preflush in order to change the wettability of rock. Therefore, when the anionic polar groups get in touch with the alkaline earth metal oxide core, spooning compound will be generated at the interface by the influence of molecular force. This kind of compound has strong adsorption capability. It can adhere to the surface of pore and seal the formation.
Without the consideration of the interaction between various factors, we select the resistance coefficient, residual resistance coefficient, and relative change of permeability to research the matching relation between asphalt particle size and permeability.
According to the experimental data of different points, P1P2 segment is a transition section with high permeability. Pressure in this segment is low. So the asphalt particles can pass this segment smoothly. Therefore, we can analyze the injecting performance and sealing performance of asphalt particles by analyzing injection pressure difference of P2P3 and P3P4.
As can be seen from Table
Experimental results.
Permeability |
Particle sizes | Resistance coefficient | Residual resistance factor | Relative change of permeability % | ||||||
---|---|---|---|---|---|---|---|---|---|---|
Average | Front | End | Average | Front | End | Average | Front | End | ||
500 | 0.02 | 19.27 | 22.16 | 15.94 | 7.77 | 6.96 | 8.7 | 87.13 | 85.64 | 88.5 |
0.02–0.06 | 24.32 | 39.24 | 7.25 | 8.78 | 13.29 | 3.62 | 88.62 | 92.48 | 72.4 | |
0.06–0.08 | 28.04 | 46.84 | 6.52 | 12.5 | 20.89 | 2 | 92.00 | 95.21 | 65.5 | |
0.08–0.1 | 33.11 | 56.96 | 5.80 | 17.06 | 30.38 | 1.81 | 94.14 | 96.71 | 44.8 | |
0.1–0.3 | 34.12 | 60.12 | 4.35 | 20.27 | 36.71 | 1.45 | 95.07 | 97.28 | 65.5 | |
|
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1000 | 0.02 | 9.46 | 10.13 | 8.7 | 6.76 | 5.06 | 8.7 | 85.20 | 80.25 | 88.5 |
0.02–0.06 | 17.57 | 19.94 | 14.13 | 6.08 | 6.65 | 6.52 | 83.56 | 84.2 | 82.75 | |
0.06–0.08 | 20.27 | 24.05 | 15.94 | 5.41 | 7.59 | 2.9 | 81.50 | 86.83 | 65.5 | |
0.08–0.1 | 21.62 | 26.88 | 17.88 | 6.42 | 10.12 | 2.17 | 84.42 | 90.12 | 54 | |
0.1–0.3 | 25.68 | 27.84 | 23.19 | 8.78 | 15.19 | 1.45 | 88.62 | 93.42 | 31 | |
|
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2000 | 0.02 | 4.73 | 6.30 | 2.90 | 6.08 | 3.8 | 8.7 | 83.56 | 73.67 | 88.5 |
0.02–0.06 | 9.5 | 10.10 | 8.70 | 5.41 | 2.53 | 8.7 | 81.50 | 60.5 | 88.5 | |
0.06–0.08 | 11.49 | 12.70 | 10.10 | 5.41 | 3.8 | 7.25 | 81.50 | 73.67 | 86.2 | |
0.08–0.1 | 12.67 | 14.24 | 10.87 | 6.33 | 7.12 | 5.43 | 84.21 | 85.96 | 81.6 | |
0.1–0.3 | 16.22 | 20.25 | 11.59 | 9.46 | 15.19 | 2.89 | 89.43 | 93.42 | 65.5 |
Core cleaving comparison chart.
When the core permeability is high (>1000 mD), the particles of small size have a good transport capability. But their flow resistance in the core is lower. In this case, when the asphalt particle size increased within a certain range, the transmission ability of the particles migration will not be affected and the injection pressure will be improved. But when the particle size is over large, the ability of particle’s transmission and migration will decrease. That means those particles gather in the injection side and cause the blocking in the near bore area. It can also cause the increase of the injection pressure and the decrease of the produced fluid volume. As we can see, when we choose the asphalt particle for different reservoirs with different permeability, we should consider the transmission ability as well as whether the particles can achieve a high penetrating resistance. We can reach the goal of profile control of deep reservoirs, improve the fluid diversion, enlarge the swept volume, and enhance oil recovery in this way.
In conclusion, the relationship between the different permeability formations and matching different size particles of asphalt has been established.
Through Table
Relative relationship.
Water permeability (mD) | Pore throat size of core ( |
Grains of asphalt ( |
Relative relationship (particle size/pore throat size) |
---|---|---|---|
500 | 36.77 | 20 | 54.39% |
1000 | 62.14 | 20–60 | 32.18%–96.55% |
2000 | 103.28 | 80–100 | 77.45%–96.8% |
The concentration of asphalt particles has a significant effect on the sealing performance. Under the condition of the constant injection pore volume, when the concentration decreases and less particles enter into the core, the residual resistance factor and relative change of permeability become smaller. In the condition to make sure that the permeability and asphalt particle size keep constant, we are studying the effect of concentration for the sealing performance.
In this experiment, by the conclusion which we got in the study about matching relation between particle size and permeability, in the study of the core permeability of 500 mD, 1000 mD, and core 2000 mD, we use the asphalt particle with the size of 0.02 mm, 0.02–0.06 mm, and 0.08–0.1 mm to do the experiment. Without considering the circumstances of the interaction between various factors, select the three parameters (resistance coefficient, residual resistance factor, and relative change of permeability) to study the matching relation between asphalt particle concentration and permeability. According to amount of measured data of pressure measuring point, we can analyze the performance of asphalt particles injection and sealing performance.
From Table
Experimental results.
Permeability |
Particle sizes (mm) | Concentration (mg/L) | Resistance coefficient | Residual resistance factor | Relative change of permeability % | ||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Average | Front | End | Average | Front | End | Average | Front | End | |||
500 | 0.02 | 1000 | 6.39 | 7.56 | 5.05 | 2.5 | 2.5 | 2.16 | 57.54 | 60.34 | 53.82 |
0.02 | 3000 | 19.27 | 22.16 | 15.94 | 6.96 | 6.96 | 8.7 | 87.13 | 85.64 | 88.5 | |
0.02 | 5000 | 25.05 | 26.64 | 23.23 | 10.78 | 10.78 | 8.71 | 89.81 | 90.72 | 88.81 | |
|
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1000 | 0.02–0.06 | 1000 | 4.75 | 7.63 | 4.37 | 3.39 | 3.81 | 2.91 | 70.52 | 73.77 | 65.64 |
0.02–0.06 | 3000 | 17.57 | 19.94 | 14.13 | 6.08 | 6.65 | 6.52 | 83.56 | 84.2 | 82.75 | |
0.02–0.06 | 5000 | 29.06 | 34.19 | 24.65 | 8.11 | 10.13 | 5.8 | 87.67 | 90.13 | 82.75 | |
|
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2000 | 0.08–0.1 | 1000 | 8.87 | 9.50 | 8.15 | 5.07 | 7.12 | 2.72 | 80.27 | 85.96 | 63.21 |
0.08–0.1 | 3000 | 12.67 | 14.24 | 10.87 | 6.33 | 7.12 | 5.43 | 84.21 | 85.96 | 81.6 | |
0.08–0.1 | 5000 | 24.07 | 30.85 | 16.30 | 8.87 | 11.87 | 5.43 | 88.72 | 91.57 | 81.6 |
Relationship between resistance evaluation parameters and asphalt particles concentration (500 mD).
Although the three parameters are increasing with the concentration, its variation does not meet certain principle. So according to the data in the table, we can analyze the relationship between the particle size and stability: the smaller the particle size, the larger the effect of the concentration on the stability. This is primarily due to the small particle aggregation which is more serious than larger particles. In addition, the larger the particle size, the more rapid the precipitation. Stable performance is better with the larger particle size, and the factors of which large particles influence the stability are mainly settling.
Similarly, from Table
Relationship between resistance evaluation parameters and asphalt particles concentration (1000 mD).
Relationship between resistance evaluation parameters and asphalt particles concentration (2000 mD).
The relation between injection pressure and injected volume in different concentrations could be discovered in Figures
The plot of the injection pressure (diameter: 0.02 mm, concentration: 1000 mg/L).
The plot of the injection pressure (diameter: 0.02 mm, concentration: 3000 mg/L).
The plot of the injection pressure (diameter: 0.02 mm, concentration: 5000 mg/L).
The plot of the injection pressure (diameter: 0.02–0.06 mm, concentration: 1000 mg/L).
The plot of the injection pressure (diameter: 0.02–0.06 mm, concentration: 3000 mg/L).
The plot of the injection pressure (diameter: 0.02–0.06 mm, concentration: 5000 mg/L).
The plot of the injection pressure (diameter: 0.08–0.1 mm, concentration: 1000 mg/L).
The plot of the injection pressure (diameter: 0.08–0.1 mm, concentration: 3000 mg/L).
The plot of the injection pressure (diameter: 0.08–0.1 mm, concentration: 5000 mg/L).
In conclusion, particle concentration affects the compatibility significantly. The asphalt solution with concentration in 1000 mg/L–3000 mg/L has a great performance in stability and deep profile control. High concentration asphalt particle solution can be alternated with water which has a great performance in this way. At the same time, the relationship between injection pressure and injected volume under different concentration has been studied. Asphalt particle injection pressures rise in a row, and the pressure rising trend has a significant difference with polymer flooding. The regularity on particle accumulation and continuous phase viscosity control are different from polymer flooding. Therefore, pressure changing needs to be paid close attention in worksite, and the time interval of pressure surveillance should be shortened.
In order to avoid asphalt precipitation in the experiments, we added a blender to the piston vessel and enlarged the pipeline inner diameter from 3 mm to 6 mm, allowing asphalt particles to keep suspending in water, thus making the simulation environment more close to the actual formation. To ensure that the asphalt particles enter the core successfully, we added a high permeability segment at the injection end of every core, in order to avoid blocking at the injection end. We measured pressures of different sections after injecting asphalt micro-emulsion and got the resistance coefficient, residual resistance factor, and relative change of permeability of different part of the cores, thus evaluating the asphalt particles’ capability to change mobility and to reduce the relative permeability of water. By analyzing the dynamic similarity of both ends of cores, we finally got the matching relationship of asphalt particles and core permeability; that is, cores of 500 mD, 1000 mD, and 2000 mD correspond with asphalt particles of 0.02 mm, 0.02–0.06 mm, and 0.08–0.1 mm, respectively. The concentration of asphalt particle has an important influence on the injection performance and sealing performance. When the particle size is constant, the lower the concentration of asphalt particle solution is, the more stable they are. Modified sulfonate asphalt profile control agents’ flow ability and relative stability are not affected by carrying liquid. It is cheap and has no corrosion on equipment. Asphalt particle solution with concentration in 3 g/L and particle size in 0.08–0.1 mm has great compatibility with high permeability layer of Daqing Lamadian Oilfield with permeability in 2
Chengfeng Ren, Junjian Li, Yiqiang Li, Jingshu Yuan, Yanqiang Xi, Kang Xiao, and Yuxi Wang declared that there are no competing interests regarding the publication of this paper, in 2015/10/1.
The authors would like to thank the Scientific Research Foundation of China National Offshore Oil Corporation (no. YXKY-2014-ZY-03) for funding this research.