RU2241829C1 - Method for treatment of face-adjacent area of productive bed - Google Patents

Abstract

FIELD: oil extractive industry.

SUBSTANCE: method includes lowering tubing pipes to face. Before pumping treating compound well liquid is replaced with hydrocarbon liquid, for example, water-less oil. Treating compound is pumped and partially pushed into bed. Level of hydrocarbon liquid in well shaft is lowered down to mark at which bed pressure is in 1.5-2 times greater than face pressure. Under such conditions implosive treatment is performed. Then tubing pipes are raised to surface, ultrasound waves emitter is lowered and ultrasound treatment of face-adjacent bed area is performed range-wise in upward direction at each meter of perforated bed thickness. Method may be used in deposits with low and normal bed pressures, in wells with bad collector properties of face-adjacent bed area, and for completing wells completed by drilling and after maintenance.

EFFECT: higher productiveness.

1 tbl, 1 ex

Description

The proposal relates to the oil industry, in particular to methods for integrated treatment of the bottom-hole zone (BHP) of the reservoirs, for example, by the influence of processing compounds in combination with ultrasonic treatment and can be used for the BHT to intensify the flow of oil in wells with reduced reservoir pressure in the fields that entered into late stage of development.

A known method of SCR wells (see. Reference “Chemical reagents in the production and transportation of oil.” Rakhmankulov D.A. et al. M., Chemistry, 1987, pp. 72-89), including the selection of wells, which in the process the operation, technological and hydrodynamic indicators decreased, as well as the performance of the pump, the descent into the well of tubing (tubing) to the bottom of the treated formation, injection of distillate (hydrocarbon composition), bringing it to the formation, pumping anhydrous oil into the formation, well shutdown at the well technological issue rzhku.

The advantage of this method is that there is an intensification of oil flow due to improved filtration properties of the reservoir.

The disadvantage of this method is that the efficiency of cleaning the bottom-hole zone remains low, because only partial cleaning of the pore volume of the formation occurs.

There is also known a method of SCR formation in production and injection wells (see Simkin EM and other Vibromagnet and vibroseismic methods of influencing oil reservoirs. Overview. Series “Oil business”, M., VNIIOENG, 1989, p. 15-20), which consists in the fact that in the well in the interval of the reservoir, an acoustic emitter is installed and the formation is processed.

The method allows to clean the PZP of mechanical impurities, dirt, paraffin and salts.

The disadvantage is that the ultrasonic treatment of the formation is carried out in a borehole fluid (in oil or in water), which has low physicochemical activity. Moreover, if there is water on the face, which most often happens, then the effect cannot be achieved. If there is oil at the bottom of the oil, the achieved effect is also insignificant, because it depends on the energy capabilities and design of the ultrasonic emitter.

There is also known a method of SCR of an oil reservoir (see US Pat. No. 5,184,678, class E 21 B 43/24, publ. 1993), including lowering the tubing to the bottom of the well, pumping the hydrocarbon composition along the tubing string, raising the pipes to the surface , descent into the well and placement of a hydro-pulse wave generator against the reservoir, and treatment of the bottom-hole formation zone with a hydrocarbon composition in hydrodynamic mode.

The effectiveness of hydroimpulse effects on the bottomhole formation zone in the environment of the treatment composition is significantly higher than in oil or in water, due to the additional physico-chemical effect of the treatment composition. However, the effectiveness of the integrated impact is reduced due to the fact that the exposure process covers a small borehole zone, into which the processing compound manages to penetrate.

The closest in technical essence and the achieved result to the proposed one is a method for processing the bottom-hole formation zone (see US Pat. RU No. 2108452, class E 21 V, 43/25, Bull. No. 10 from 04/10/98). Tubing to the bottom of the tubing, pumping of the treatment compound along it, raising the pipes to the surface, lowering the ultrasonic emitter into the well on the cable and placing it against the treatment interval of the formation, treating the formation with ultrasound in the medium of the treatment composition, additionally perforating the casing before processing the formation bottom of the column in the interval of the reservoir in the environment of the processing composition. Ultrasonic treatment of the formation is carried out upon receipt of the processing composition in the formation, and then from the formation into the well.

The method allows to increase the effectiveness of the treatment composition on the reservoir due to the simultaneous complex effects, namely hydrodynamic, physico-chemical, ultrasonic, with a deep penetration of the treatment composition into the formation.

However, it is known that most of the oil fields of the Russian Federation entered the late stage of development, when the energy of the formation was significantly reduced, the processing compound penetrates well into the formation and returns very poorly from it. Repeated perforation in this case only contributes to the penetration of the processing composition, and sometimes it helps to increase the water content of the product. Therefore, the processing efficiency is reduced and becomes short-term.

The technical task of the proposed method for treating the bottom-hole zone of a productive formation is to increase the efficiency of an integrated oil recovery zone due to the intensification of oil inflow in wells with reduced formation pressure in fields that have entered the late stage of development.

The problem is achieved by the described method of SCR of a productive formation, including the descent of tubing to the bottom, pumping of the treatment compound along them, lifting of the tubing to the surface, descent into the well and placement of an ultrasonic emitter against the treated formation and ultrasonic treatment of the formation in the processing medium .

What is new is that before injecting the treatment fluid, the well fluid is replaced with hydrocarbon fluid (commercial oil, diesel fuel, etc.), the treatment fluid is pumped and partially pushed into the reservoir, the level of hydrocarbon fluid in the wellbore is reduced to the point at which the reservoir pressure one and a half to two times the bottomhole pressure and under these conditions, successively perform implosion exposure and ultrasonic treatment of the bottomhole formation zone, and ultrasonic processing is carried out by interval, from below upwards, each meter perforated layer thickness.

The method is as follows. A tubing string is lowered into the well, before artificial slaughter. The injection of salable anhydrous oil into the annular space replaces the borehole fluid in the full volume of the wellbore. In this case, the face is cleaned of dirt and water and the bottomhole pressure decreases. Then, the tubing is pumped into the face along the tubing string and the treatment composition is partially pressed into the formation. After that, the shoe of the tubing string is lifted to the interval to which the level will decrease. The oil level in the well is reduced to the point at which the reservoir pressure will double the bottomhole pressure. After that, the tubing string rises to the surface. Next, an implosion chamber is lowered onto the cable into the formation zone and an implosive effect is produced on the formation, as a result of which large particles of contaminants are extracted, then an ultrasonic emitter is lowered onto the cable into the formation zone and is set at the level of the lower meter of the perforated formation thickness. An ultrasonic effect is produced within 30-40 minutes, then the emitter rises 1 meter higher and again 30-40 minutes of ultrasonic exposure. And so on every meter of the perforated thickness of the reservoir. At this SCF is completed, pumping equipment is launched, and the well is put into operation.

As a result of such a complex effect on the bottom-hole zone of a productive formation, the pore space is completely cleaned of all types of contaminants and removed from the formation into the wellbore.

An example of a specific implementation of the method

Tests of the method were carried out at well No. 1280 of the Bavlinskoye field. Six months ago, a prototype treatment was carried out at the well. Received an increase in flow rate of 1.5 tons, which lasted 3 months. Therefore, it was decided to try the proposed method.

Geological and technical characteristics of the well.

1. Productive horizon

2. Artificial slaughter 1760 m

3. The interval of perforation 1745-1750 m

4. The reservoir pressure of 13.0 MPa

5. The flow rate of the well 3,5 m ³ / day

6. Water cut 25%

7. Dynamic level 1300 m

8. Static level 250 m

9. The coefficient of productivity of 0.01 tons / day ATM

First, pumping equipment was removed from the well. A tubing string was lowered into the well to a depth of 1759 m. With an open gate valve on the tubing, using the CA-320 pumping unit, 20 m ^{3 of} anhydrous salable oil was pumped into the annulus at the highest possible speed, without stopping. The pumping unit was switched to the tubing string and with an open valve on the annulus pumped into the tubing and forced into the annulus to the top of the formation 6 m ^{3 of} Nefras hydrocarbon solvent. They closed the valve on the annulus and pumped oil into the tubing and pushed 2.5 m ³ Nefras into the reservoir. The shoe of the tubing string was raised to an interval of 1100 m. Using a swab, the oil level in the well was reduced to 1000 m. The tubing string was raised to the surface. The implosion chamber, consisting of 2 tubing pipes, was lowered into the well, into the zone of the productive formation, on the cable and had an implosive effect on the formation in the interval of 1748 and 1746 m. The implosion chamber was raised. The ultrasonic emitter was lowered on the cable to an interval of 1749.5 m. An ultrasonic effect was made on the formation for 40 minutes. Then an ultrasonic effect was made in the intervals of 1748.5 m - 1747.5 m - 1746.5 m - 1745.5 m. The ultrasonic emitter was raised. They lowered the pumping equipment and put the well into operation. After 10 days, hydrodynamic studies were performed and the operating parameters of the well were established (see table).

As you can see from the table, the flow rate increased by 3 tons, the dynamic level increased by 550 m, and the productivity coefficient increased from 0.01 to 0.09. After 6 months, repeated hydrodynamic studies were carried out, which showed that the parameters of the well did not change. The technical and economic efficiency of the proposed method of SCR of a productive formation is due to the intensification of oil inflow in wells with reduced reservoir pressure in the fields that entered the late stage of development.

Claims (1)

A method for treating the bottom-hole zone of a productive formation, including the descent of the tubing to the bottom, pumping of the treatment compound thereon, lifting of the tubing to the surface, descent into the well and placement of an ultrasonic wave emitter against the formation to be treated, and treating the formation with ultrasound in a processing medium, characterized in that before the injection of the processing composition, the well fluid is replaced with a hydrocarbon liquid, for example, anhydrous oil, the processing composition is pumped and they are squeezed into the formation, the level of hydrocarbon fluid in the well is reduced to the point at which the formation pressure is one and a half to two times the bottomhole pressure, under these conditions, sequentially, they perform implosive exposure and ultrasonic treatment of the bottomhole formation zone, and the ultrasonic treatment is carried out intervalically, from the bottom up per meter of perforated formation thickness.