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Received 26 March 2013; accepted 8 May 2013
Abstract Aiming at solving small effective acid reaction range and causing second damage in the acidizing in low permeability reservoirs, a new kind of deep penetration and little damage complex plug removal system was developed through laboratory research, which consists of an organic acid, a phosphoric acid, an ammonium organic acid, an ammonium fluoride and a strong oxidizer. The properties were evaluated and the results indicate that it has advantages of proper dissolving capacity to rock with dissolving ratio of 38.9%, little corrosion to the pipeline of equipment with corrosion rate of 2.9 g/m2·h-1, low interfacial tension, anti-acid-sludge, and ability to stabilize ferric ion. The plugging in deep formations can be removed with low damage to rock skeleton, which the damage rate is less than 20%. It has been applied in 19 wells with success ratio of 100% and long term of validity, average validity is more than 200 days. The oil production and water injection have been increased obviously.
Keywords: Acidization; Second damage; Complex plug removal system; Deep penetration; Rock skeleton
INTRODUCTION
Acidizing plug-removal is an important measure to improve the development effect of low permeability reservoir, a lot of researches have been made on the improvement of acidification technology[1-3]. However, for special low-permeability reservoirs with small pore throat, multi-layer system, thin reservoir, serious heterogeneity in the layer, large differences in longitudinal properties, high feldspar content, co-existence of blockage by organic and inorganic matters[4], due to restrictions of their own conditions, certain problems still existed in acid injection, limited acid absorption capacity in acidification layers, fast response of acid rock, poor repeated acidification effects, difficulties in removing organic blocking, and potential secondary damage to reservoir and so on. Therefore, through a large number of laboratory experiments, a new complex plug removal system major composted of organic acids, phosphoric acid, organic ammonium, ammonium fluoride and strong oxidants is introduced.
1. EXPERIMENTAL RESEARCH
1.1 Main Experimental Instruments and Materials Main experimental instruments: CC-10-S hightemperature and high-pressure dynamic corrosion instrument (Canada), JYW-200A automatic interfacial tensiometer (Chengde Dajia Instrument Co., Ltd.), Short core flow tester (laboratory-made), long core flow tester(USA), rock triaxial tester (Changchun Rising Sun Testing instrument Co., Ltd.). Main materials: hydrochloric acid, hydrofluoric acid, sulfuric acid, boric acid, fluoboric acid, nitric acid, phosphoric acid, formic acid, acetic acid, ammonia triacetic acid, chloroacetic acid, citric acid, ammonium fluoride, organic acid salt, and etc. all are analytically or chemically pure reagents, YNW-1 stabilizer (laboratorymade), YSH-1 corrosion inhibitor (laboratory-made), YG-1303-1 ferric ion stabilizer (China University of Petroleum Yuguang Technology Co., Ltd.), surfactant(Guangzhou Achchem Technology Co., Ltd.), synergists(China University of Petroleum Yuguang Technology Co., Ltd.), chlorine dioxide solution (Hebei Cangzhou Zhengda Environmental Protection Technology Co., Ltd.), clay minerals and cores used in experiments are all provided by CL Oilfield.
1.2 Formula of the System
Deep-penetration and low-damage composite plug removal system should be featured by large effective radius and least damage to reservoir[5-6]. In this paper, acidizing fluids selected have been compounded with different additives, after core tests and formation compatibility tests, the formula of the new complex plug removal system is determined as follows (all proportions are mass percentage):
(1) Pretreatment solution: 3% of NH4Cl solution; (2) pad
fluid: 10% of hydrochloric acid + acid additives, (3) main solution: 25% of complex plug removal system (8% of organic acid and organic acid salt + 8% of phosphoric acid+ 5% of ammonium fluoride + 4% of strong oxidizer) + acid additives, (4) Over-flush fluid: 3% of NH4Cl solution.
2. RESULTS AND DISCUSSION
2.1 Erosion Performance
The core is crushed, sieved and dried obtained from C1-C2 and C3-C4 at 2605.77-2680.61 m of Well C83-2 in CL
Oilfield, under the condition that the core/plug-removing agent is 0.05 g/mL, the plug removal agent is placed in a sealed container. After thorough reaction under 95 ℃ and 60 r/min, the residual acid liquid solid is filtered out with dried and weighed quantitative filter paper, then the core erosion rate was obtained; the result is shown in Table 1. It can be known that the erosion rate of 25% of the new complex plug removal system to natural core is 38.9%, which is less than conventional earth acid but higher than YFP low damage acid and FAC deep penetrating acid currently used in the oilfield, it is indicated that this system has a strong capacity in treating formation and improving or restoring formation permeability. 2.2 Corrosion Performance
Corrosion performance is tested with the high temperature and high pressure dynamic corrosion instrument on N80 steel piece. The surface to volume ratio between the plugremoving agent and the steel piece is 15 mL/cm2. In the experiment, the rotation speed is 60 r/min, the temperature is 120 ℃, the pressure is 15 MPa, and the reaction time is 4 hours. The evaluation target should be in compliance with SY5405-1996《Performance Test Method and Evaluation Indicator of Acidification Inhibitor Used in Acidizing Operation》, and the experiment result is shown in Table 1. It can be known that the corrosion rate of the new complex plug removal system is the minimum under high temperature, high pressure and dynamic conditions. When the temperature is 120 ℃ and the pressure is 15 MPa, the corrosion rate is only 2.9 g/m2·h-1. Using this system to remove plug will cause least corrosion to the pipeline.
2.3 Surface (Interfacial) Tension
In the experiments, JYW-200A automatic interfacial tensimeter is used, and the experiment temperature is 25 ℃. The experiment result is shown in Table 1. It can be seen from Table 1 that new complex plug removal system has good surface activity, and the surface tension is 20.9 mN/m while the interfacial tension is 1.7 mN/m, which can effectively reduce the surface (interfacial) tension of the acid.
2.4 Anti-Acid-Residue Performance
The conventional earth acid, YFP low-damage acid, FAC deep-penetration acid, and the new complex plug removal system is respectively mixed with dehydrated crude oil (with a paraffin content of 20% and a gel content of 20%) from Well 85-3 at 1:1 ratio (20 mL plug removing agent: 20 mL crude oil). After 2 h of reaction under
95 ℃, the solution is filtered with a sieve and cleaned with organic solvent, then the acid residue is dried and weighed, the result is shown in Table 1. Compared with conventional earth acid, YFP low-damage acid and FAC deep penetration acid, the acid residue generated from the reaction between the new complex plug removal system with crude oil from Well C85-3 is greatly reduced, which indicates that the new complex plug removal system can prevent the formation of acid residue due to the reaction between acidizing fluid and crude oil.
2.5 Performance of Stabilizing Ferrous Ion
Ferric sulfate is added in 100 mL of 25% new complex plug removal system till the Fe3+ concentration is 800 mg/L. Then 100g quartz sand pre-treated with 15% HCl is added, After that, the new complex plug removal system is put into 90 oC constant temperature water bath. After 24 h, no precipitation can be seen generated from the new complex plug removal system, which indicates that Fe3+ can remain stable in the new complex plug removal system and ferric hydroxide precipitation is not prone to occur, thus it is conducive to preventing secondary sedimentation generated from acidification. 2.6 Plug-Removing Performance
H+ existed in the new complex plug removal system and HF gradually released described can corrode lime composition, ferrous compounds, siliceous, and argillaceous obstruction and release inorganic plug. The strong oxidant in the system is water solution containing stable chlorine dioxide, which can release strong oxidizing atomic-state free radicals ClO2 - and ClO2 -when the pH is below 2.5, relying on its strong oxidizing ability, heavy hydrocarbons can be oxidized, degraded and dissolved. Polymers, guar gum and other polymers can be oxidized and degraded, thus releasing the organic plug. At the same time, it has a strong bactericidal capacity and can kill the sulfate-reducing bacteria and clear the bacteria metabolites.
In plug-removing simulation experiment, the experiment temperature is determined according to the actual situation of reservoir in C83 block. According to acid injection procedure of acidification operation, the pre-pad fluid, pre-pad acid, main plug-removing fluid and over flush fluid was injected successively. Core plugremoving effect was determined according to the ratio between permeability when injecting flush fluid and prepad fluid (K4 -/K1 -). The core is taken from Well C83-2, the temperature is 90 ℃, the experiment flow speed is 5 mL/min, the core diameter is 25 mm and the core length is 50~70 mm. The experiment result is shown in Table 2.
It can be known from Table 2 that all of four plugremoving systems have a good plug-removing effect, mainly because that the core is short and the secondary sediment generated is taken away from the core by the fluid. However, the effect of the four plug-removing systems in improving the core permeability (K4 -/K1 -) varies widely, and the new complex plug removal system is significantly better than YFP low-damage acid, FAC deep penetration acid and conventional earth acid. Through analysis, it is believed that the reasons are as follows, after the acid corrodes sandstone core and thus increases the penetration substantially, secondary damage will be caused to the core, which results in the reduction of permeability. At the same time, in the new complex plug removal system, phosphoric acid/hydrofluoric acid reacts with the carbonate rock, generating fluorine calcium carbonate(phosphate of lime), and soon a layer of covering membrane forms on the surface of the carbonatite, which can prevent the carbonatite from continuing to dissolve, thus reducing the generation of CaF2 precipitate. The organic acids and organic acid salt in the system form a buffer system, which maintains the pH at a lower value (pH< 2) and also has good complication properties and can chelate multivalent metal ions (eg. Fe3+, Al3+), thus it can reduce concentration of Fe3+ and Al3+ in the acid residue and avoid Fe(OH)3 and Al(OH)3 and other precipitations, so it can reduce the secondary damage to reservoir. 2.7 Deep-Penetration Performance
Three long cores (linked in series) are used to conduct plug-removing flow simulation experiment, and their plug-removing effects are compared with that of conventional earth acid, YFP low-damage acid, and FAC deep-penetration acid commonly used in domestic oilfields, as is shown in Table 3.
It can be known from Table 3 that when the main plug-removing agent injected is conventional earth acid, compared with the original permeability, the permeability of the three cores after plug-removing is reduced rather than increased. At the same time, the core permeability increases after plug-removing with other three plugremoving systems, among which the new complex plug removal system achieves the best effect. The permeability of the first core increases by 5.29 times, while that of the second and the third core increases by 2.47 times and 1.85 times respectively. Through analysis, it is believed the causes are as follows, due to secondary damage after acidification of conventional earth acid, the permeability is reduced. Meanwhile, as organic acid and phosphoric acid in the new complex plug removal system are polybasic acid with a small ionization constant, according to chemical kinetics, which belongs to secondary reaction. Therefore, due to the low concentration of active acid concentration, the acidrock reaction rate is also relatively low. Organic acids and organic acid salt, as well as phosphoric acid and its acidification product, dihydric phosphate salt, can form a buffer solution, making the acidizing fluid releasing H+ gradually in the acid-rock reaction process, thus it is ensured that the plug-removing fluid still has a certain concentration of active HF after reaching the deep part of the formation and can continue to react with the formation, with deep penetration to the core dissolution, conducive to plug-removing in deep layers.
2.8 Low-Damage Performance
The erosion of acidizing fluid to blocking matters and minerals in the reservoir will increase the permeability of the reservoir and improve the injecting capacity, but it will also reduce the intensity of rock. The excessive erosion of the rock will destroy the formation skeleton, or even result in the later sanding and pore-collapse[7]. After the long core plug-removing experiments, compression strength of rock is measured with different hole sections, at the same time the compression strength is measured before plug-removing of cores from the same hole section, using this method to evaluate the degree of impact of the plugremoving fluid on rock skeleton and calculate the rate of damage, the result is as shown in Table 4.
It can be known from Table 4 that the core compression strength changes before and after plug-removing, which indicates that the core is damaged to different degrees after the plug-removing fluid acts on the core, that is mainly because the action of acidizing liquid changes the structure of core. Different plug-removing system caused different degrees of damage. Conventional earth acid causes the largest degree of damage, which is above 40%, followed by FAC deep-penetration acid and YFP low damage-acid. The new complex plug removal system causes the lowest degree of damage. After long core plugremoving, the degree of damage on compression strength of the first core is 16.7%, and that of the second and the third cord is 16.5% and 13.3% respectively. The degree of damage of the three cores is less than 20%, it is indicated that it has minimal damage to the rock skeleton, and with the injection of plug-removing fluid, the H+ concentration is reduced, and thus the impact on the compression strength of rock is weakened.
3. FIELD APPLICATION AND EFFECT ANALYSIS
The first field test has been applied for 19 well times in wells of CL Oilfield, including in 10 water wells and 9 oil wells with full success. The cumulated injection increment is 71,000 m3, with an average single well injection increment of 710 m3, the average effective period over 250 days, with an average reduction of injection pressure of 5.8 MPa. In 9 oil wells, with effectiveness of 100%, the cumulative oil increment is 4587 t, with an average single well oil increment of 509.6 t, the average effective period reaches 220 d, achieving a favorable production increasing and injection augmenting effect.
4. ECONOMIC EFFECT ANALYSIS
4.1 Direct Economic Effect of Water Well Acidification
The low-damage acid has been applied for 10 well times in water injection wells, achieving a cumulated injection increment of 71,000 m3. It maintains the formation energy and slows the decreasing of crude oil production. The oil production of the corresponding oil well reaches about 3,800 t. Assuming the price of stimulated oil increment to be RMB 3,500/t, and the well acidification cost to be RMB 300,000/well time, the direct economic effect of well acidification and augmented injection is:
The crude oil production of corresponding oil well ×price of stimulated oil increment - well acidification and augmented injection cost = 3800×3500-400,000×10= 9,300,000 (RMB). 4.2 Direct Economic Effect of Oil Well Acidification
This system has been applied for 9 well times in oil wells, achieving a cumulated oil increment of 4,332 t. Assuming the price of stimulated oil increment to be RMB 3,500/t, and the well acidification cost to be RMB 400,000/well, the direct economic effect of low-damage acidification is:
Oil increment ×price of stimulated oil increment - oil well acidification cost = 4332 × 3500 - 400,000 × 9 = 11,562,000 (RMB).
CONCLUSIONS
(1) The new complex plug removal system developed has features of appropriate erosion capacity, low corrosion rate, low surface tension, strong anti-acid-residue and Fe3+ stabilizing capacity.
(2) This system can increase the permeability of lowpermeability reservoirs greatly, which has characteristics of deep penetrating and speed-lowering performance. It has the least damage to the rock skeleton, with a degree of damage less than 20%, which can effectively avoid secondary contamination caused by conventional earth acid.
(3) Field application results show that this system is fully effective in plug-removing, and it has a long effective period, with an average greater than 200 days. It has obvious production increasing and injection augmenting effect and can bring favorable economic effect.
REFERENCES
[1] Li, D. P. (1997). Exploration of Sand Oilfield with Low Permeability (pp. 166-168). Beijing: Petroleum Industry Press.
[2] Ali, S. A., et al. (2006, February). Effective Stimulation of High-Temperature Sandstone Formations in East Venezuela with a New Sandstone-Acidizing System. International Symposium and Exhibition on Formation Damage Control, Lafayette, Louisiana U.S.A.
[3] Uchendu, C., Obadare, A., & Nwoke, L. (2004). Solvent/ Acid Blend Provides Economic Single Step Matrix Acidizing Success for Fines and Organic Damage Removal in Sandstone Reservoirs: a Niger-Delta Case Study. SPE Annual Technical Conference and Exhibition, 26-29 September 2004, Houston, Texas.
[4] Pongratz, R., Kontarev, R., & Robertson, B. (2005, May). Optimizing Matrix Acid Treatments in a Multi-Layered Reservoir in Russia by Applying Different Diversion Techniques. SPE European Formation Damage Conference, Sheveningen, The Netherlands.
[5] Selle, O. M., et al. (2004, September). Gelled Organic Acid System for Improved CaCO3 Removal in Horizontal Openhole Wells at the Heidrun Field. SPE Annual Technical Conference and Exhibition, Houston, Texas.
[6] Nwoke, L., et al. (2004, April). Phosphonic Acid Complex for Stimulating HF-Sensitive Reservoirs - a Revolutionary Response. SPE/DOE Symposium on Improved Oil Recovery, Tulsa, Oklahoma.
[7] Zhou, W. F., Kang, Y., & Wang, X. (2005). Reaction Capacity of Different Acid Systems on Natural Core. Journal of Daqing Petroleum Institute, 29(5), 48-50.
Abstract Aiming at solving small effective acid reaction range and causing second damage in the acidizing in low permeability reservoirs, a new kind of deep penetration and little damage complex plug removal system was developed through laboratory research, which consists of an organic acid, a phosphoric acid, an ammonium organic acid, an ammonium fluoride and a strong oxidizer. The properties were evaluated and the results indicate that it has advantages of proper dissolving capacity to rock with dissolving ratio of 38.9%, little corrosion to the pipeline of equipment with corrosion rate of 2.9 g/m2·h-1, low interfacial tension, anti-acid-sludge, and ability to stabilize ferric ion. The plugging in deep formations can be removed with low damage to rock skeleton, which the damage rate is less than 20%. It has been applied in 19 wells with success ratio of 100% and long term of validity, average validity is more than 200 days. The oil production and water injection have been increased obviously.
Keywords: Acidization; Second damage; Complex plug removal system; Deep penetration; Rock skeleton
INTRODUCTION
Acidizing plug-removal is an important measure to improve the development effect of low permeability reservoir, a lot of researches have been made on the improvement of acidification technology[1-3]. However, for special low-permeability reservoirs with small pore throat, multi-layer system, thin reservoir, serious heterogeneity in the layer, large differences in longitudinal properties, high feldspar content, co-existence of blockage by organic and inorganic matters[4], due to restrictions of their own conditions, certain problems still existed in acid injection, limited acid absorption capacity in acidification layers, fast response of acid rock, poor repeated acidification effects, difficulties in removing organic blocking, and potential secondary damage to reservoir and so on. Therefore, through a large number of laboratory experiments, a new complex plug removal system major composted of organic acids, phosphoric acid, organic ammonium, ammonium fluoride and strong oxidants is introduced.
1. EXPERIMENTAL RESEARCH
1.1 Main Experimental Instruments and Materials Main experimental instruments: CC-10-S hightemperature and high-pressure dynamic corrosion instrument (Canada), JYW-200A automatic interfacial tensiometer (Chengde Dajia Instrument Co., Ltd.), Short core flow tester (laboratory-made), long core flow tester(USA), rock triaxial tester (Changchun Rising Sun Testing instrument Co., Ltd.). Main materials: hydrochloric acid, hydrofluoric acid, sulfuric acid, boric acid, fluoboric acid, nitric acid, phosphoric acid, formic acid, acetic acid, ammonia triacetic acid, chloroacetic acid, citric acid, ammonium fluoride, organic acid salt, and etc. all are analytically or chemically pure reagents, YNW-1 stabilizer (laboratorymade), YSH-1 corrosion inhibitor (laboratory-made), YG-1303-1 ferric ion stabilizer (China University of Petroleum Yuguang Technology Co., Ltd.), surfactant(Guangzhou Achchem Technology Co., Ltd.), synergists(China University of Petroleum Yuguang Technology Co., Ltd.), chlorine dioxide solution (Hebei Cangzhou Zhengda Environmental Protection Technology Co., Ltd.), clay minerals and cores used in experiments are all provided by CL Oilfield.
1.2 Formula of the System
Deep-penetration and low-damage composite plug removal system should be featured by large effective radius and least damage to reservoir[5-6]. In this paper, acidizing fluids selected have been compounded with different additives, after core tests and formation compatibility tests, the formula of the new complex plug removal system is determined as follows (all proportions are mass percentage):
(1) Pretreatment solution: 3% of NH4Cl solution; (2) pad
fluid: 10% of hydrochloric acid + acid additives, (3) main solution: 25% of complex plug removal system (8% of organic acid and organic acid salt + 8% of phosphoric acid+ 5% of ammonium fluoride + 4% of strong oxidizer) + acid additives, (4) Over-flush fluid: 3% of NH4Cl solution.
2. RESULTS AND DISCUSSION
2.1 Erosion Performance
The core is crushed, sieved and dried obtained from C1-C2 and C3-C4 at 2605.77-2680.61 m of Well C83-2 in CL
Oilfield, under the condition that the core/plug-removing agent is 0.05 g/mL, the plug removal agent is placed in a sealed container. After thorough reaction under 95 ℃ and 60 r/min, the residual acid liquid solid is filtered out with dried and weighed quantitative filter paper, then the core erosion rate was obtained; the result is shown in Table 1. It can be known that the erosion rate of 25% of the new complex plug removal system to natural core is 38.9%, which is less than conventional earth acid but higher than YFP low damage acid and FAC deep penetrating acid currently used in the oilfield, it is indicated that this system has a strong capacity in treating formation and improving or restoring formation permeability. 2.2 Corrosion Performance
Corrosion performance is tested with the high temperature and high pressure dynamic corrosion instrument on N80 steel piece. The surface to volume ratio between the plugremoving agent and the steel piece is 15 mL/cm2. In the experiment, the rotation speed is 60 r/min, the temperature is 120 ℃, the pressure is 15 MPa, and the reaction time is 4 hours. The evaluation target should be in compliance with SY5405-1996《Performance Test Method and Evaluation Indicator of Acidification Inhibitor Used in Acidizing Operation》, and the experiment result is shown in Table 1. It can be known that the corrosion rate of the new complex plug removal system is the minimum under high temperature, high pressure and dynamic conditions. When the temperature is 120 ℃ and the pressure is 15 MPa, the corrosion rate is only 2.9 g/m2·h-1. Using this system to remove plug will cause least corrosion to the pipeline.
2.3 Surface (Interfacial) Tension
In the experiments, JYW-200A automatic interfacial tensimeter is used, and the experiment temperature is 25 ℃. The experiment result is shown in Table 1. It can be seen from Table 1 that new complex plug removal system has good surface activity, and the surface tension is 20.9 mN/m while the interfacial tension is 1.7 mN/m, which can effectively reduce the surface (interfacial) tension of the acid.
2.4 Anti-Acid-Residue Performance
The conventional earth acid, YFP low-damage acid, FAC deep-penetration acid, and the new complex plug removal system is respectively mixed with dehydrated crude oil (with a paraffin content of 20% and a gel content of 20%) from Well 85-3 at 1:1 ratio (20 mL plug removing agent: 20 mL crude oil). After 2 h of reaction under
95 ℃, the solution is filtered with a sieve and cleaned with organic solvent, then the acid residue is dried and weighed, the result is shown in Table 1. Compared with conventional earth acid, YFP low-damage acid and FAC deep penetration acid, the acid residue generated from the reaction between the new complex plug removal system with crude oil from Well C85-3 is greatly reduced, which indicates that the new complex plug removal system can prevent the formation of acid residue due to the reaction between acidizing fluid and crude oil.
2.5 Performance of Stabilizing Ferrous Ion
Ferric sulfate is added in 100 mL of 25% new complex plug removal system till the Fe3+ concentration is 800 mg/L. Then 100g quartz sand pre-treated with 15% HCl is added, After that, the new complex plug removal system is put into 90 oC constant temperature water bath. After 24 h, no precipitation can be seen generated from the new complex plug removal system, which indicates that Fe3+ can remain stable in the new complex plug removal system and ferric hydroxide precipitation is not prone to occur, thus it is conducive to preventing secondary sedimentation generated from acidification. 2.6 Plug-Removing Performance
H+ existed in the new complex plug removal system and HF gradually released described can corrode lime composition, ferrous compounds, siliceous, and argillaceous obstruction and release inorganic plug. The strong oxidant in the system is water solution containing stable chlorine dioxide, which can release strong oxidizing atomic-state free radicals ClO2 - and ClO2 -when the pH is below 2.5, relying on its strong oxidizing ability, heavy hydrocarbons can be oxidized, degraded and dissolved. Polymers, guar gum and other polymers can be oxidized and degraded, thus releasing the organic plug. At the same time, it has a strong bactericidal capacity and can kill the sulfate-reducing bacteria and clear the bacteria metabolites.
In plug-removing simulation experiment, the experiment temperature is determined according to the actual situation of reservoir in C83 block. According to acid injection procedure of acidification operation, the pre-pad fluid, pre-pad acid, main plug-removing fluid and over flush fluid was injected successively. Core plugremoving effect was determined according to the ratio between permeability when injecting flush fluid and prepad fluid (K4 -/K1 -). The core is taken from Well C83-2, the temperature is 90 ℃, the experiment flow speed is 5 mL/min, the core diameter is 25 mm and the core length is 50~70 mm. The experiment result is shown in Table 2.
It can be known from Table 2 that all of four plugremoving systems have a good plug-removing effect, mainly because that the core is short and the secondary sediment generated is taken away from the core by the fluid. However, the effect of the four plug-removing systems in improving the core permeability (K4 -/K1 -) varies widely, and the new complex plug removal system is significantly better than YFP low-damage acid, FAC deep penetration acid and conventional earth acid. Through analysis, it is believed that the reasons are as follows, after the acid corrodes sandstone core and thus increases the penetration substantially, secondary damage will be caused to the core, which results in the reduction of permeability. At the same time, in the new complex plug removal system, phosphoric acid/hydrofluoric acid reacts with the carbonate rock, generating fluorine calcium carbonate(phosphate of lime), and soon a layer of covering membrane forms on the surface of the carbonatite, which can prevent the carbonatite from continuing to dissolve, thus reducing the generation of CaF2 precipitate. The organic acids and organic acid salt in the system form a buffer system, which maintains the pH at a lower value (pH< 2) and also has good complication properties and can chelate multivalent metal ions (eg. Fe3+, Al3+), thus it can reduce concentration of Fe3+ and Al3+ in the acid residue and avoid Fe(OH)3 and Al(OH)3 and other precipitations, so it can reduce the secondary damage to reservoir. 2.7 Deep-Penetration Performance
Three long cores (linked in series) are used to conduct plug-removing flow simulation experiment, and their plug-removing effects are compared with that of conventional earth acid, YFP low-damage acid, and FAC deep-penetration acid commonly used in domestic oilfields, as is shown in Table 3.
It can be known from Table 3 that when the main plug-removing agent injected is conventional earth acid, compared with the original permeability, the permeability of the three cores after plug-removing is reduced rather than increased. At the same time, the core permeability increases after plug-removing with other three plugremoving systems, among which the new complex plug removal system achieves the best effect. The permeability of the first core increases by 5.29 times, while that of the second and the third core increases by 2.47 times and 1.85 times respectively. Through analysis, it is believed the causes are as follows, due to secondary damage after acidification of conventional earth acid, the permeability is reduced. Meanwhile, as organic acid and phosphoric acid in the new complex plug removal system are polybasic acid with a small ionization constant, according to chemical kinetics, which belongs to secondary reaction. Therefore, due to the low concentration of active acid concentration, the acidrock reaction rate is also relatively low. Organic acids and organic acid salt, as well as phosphoric acid and its acidification product, dihydric phosphate salt, can form a buffer solution, making the acidizing fluid releasing H+ gradually in the acid-rock reaction process, thus it is ensured that the plug-removing fluid still has a certain concentration of active HF after reaching the deep part of the formation and can continue to react with the formation, with deep penetration to the core dissolution, conducive to plug-removing in deep layers.
2.8 Low-Damage Performance
The erosion of acidizing fluid to blocking matters and minerals in the reservoir will increase the permeability of the reservoir and improve the injecting capacity, but it will also reduce the intensity of rock. The excessive erosion of the rock will destroy the formation skeleton, or even result in the later sanding and pore-collapse[7]. After the long core plug-removing experiments, compression strength of rock is measured with different hole sections, at the same time the compression strength is measured before plug-removing of cores from the same hole section, using this method to evaluate the degree of impact of the plugremoving fluid on rock skeleton and calculate the rate of damage, the result is as shown in Table 4.
It can be known from Table 4 that the core compression strength changes before and after plug-removing, which indicates that the core is damaged to different degrees after the plug-removing fluid acts on the core, that is mainly because the action of acidizing liquid changes the structure of core. Different plug-removing system caused different degrees of damage. Conventional earth acid causes the largest degree of damage, which is above 40%, followed by FAC deep-penetration acid and YFP low damage-acid. The new complex plug removal system causes the lowest degree of damage. After long core plugremoving, the degree of damage on compression strength of the first core is 16.7%, and that of the second and the third cord is 16.5% and 13.3% respectively. The degree of damage of the three cores is less than 20%, it is indicated that it has minimal damage to the rock skeleton, and with the injection of plug-removing fluid, the H+ concentration is reduced, and thus the impact on the compression strength of rock is weakened.
3. FIELD APPLICATION AND EFFECT ANALYSIS
The first field test has been applied for 19 well times in wells of CL Oilfield, including in 10 water wells and 9 oil wells with full success. The cumulated injection increment is 71,000 m3, with an average single well injection increment of 710 m3, the average effective period over 250 days, with an average reduction of injection pressure of 5.8 MPa. In 9 oil wells, with effectiveness of 100%, the cumulative oil increment is 4587 t, with an average single well oil increment of 509.6 t, the average effective period reaches 220 d, achieving a favorable production increasing and injection augmenting effect.
4. ECONOMIC EFFECT ANALYSIS
4.1 Direct Economic Effect of Water Well Acidification
The low-damage acid has been applied for 10 well times in water injection wells, achieving a cumulated injection increment of 71,000 m3. It maintains the formation energy and slows the decreasing of crude oil production. The oil production of the corresponding oil well reaches about 3,800 t. Assuming the price of stimulated oil increment to be RMB 3,500/t, and the well acidification cost to be RMB 300,000/well time, the direct economic effect of well acidification and augmented injection is:
The crude oil production of corresponding oil well ×price of stimulated oil increment - well acidification and augmented injection cost = 3800×3500-400,000×10= 9,300,000 (RMB). 4.2 Direct Economic Effect of Oil Well Acidification
This system has been applied for 9 well times in oil wells, achieving a cumulated oil increment of 4,332 t. Assuming the price of stimulated oil increment to be RMB 3,500/t, and the well acidification cost to be RMB 400,000/well, the direct economic effect of low-damage acidification is:
Oil increment ×price of stimulated oil increment - oil well acidification cost = 4332 × 3500 - 400,000 × 9 = 11,562,000 (RMB).
CONCLUSIONS
(1) The new complex plug removal system developed has features of appropriate erosion capacity, low corrosion rate, low surface tension, strong anti-acid-residue and Fe3+ stabilizing capacity.
(2) This system can increase the permeability of lowpermeability reservoirs greatly, which has characteristics of deep penetrating and speed-lowering performance. It has the least damage to the rock skeleton, with a degree of damage less than 20%, which can effectively avoid secondary contamination caused by conventional earth acid.
(3) Field application results show that this system is fully effective in plug-removing, and it has a long effective period, with an average greater than 200 days. It has obvious production increasing and injection augmenting effect and can bring favorable economic effect.
REFERENCES
[1] Li, D. P. (1997). Exploration of Sand Oilfield with Low Permeability (pp. 166-168). Beijing: Petroleum Industry Press.
[2] Ali, S. A., et al. (2006, February). Effective Stimulation of High-Temperature Sandstone Formations in East Venezuela with a New Sandstone-Acidizing System. International Symposium and Exhibition on Formation Damage Control, Lafayette, Louisiana U.S.A.
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