RU2726096C1 - Method for completion of construction of production well with horizontal end of wellbore - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to oil and gas industry, namely, to development of oil, gas and gas condensate fields. Proposed method comprises lowering and fitting of cementless shank-filter into horizontal end of wellbore with disconnecting packers, multi-stage hydraulic fracturing ports and flow regulators. Then, tubing string is lowered with complex of underground equipment to design depth, input of tubing string is made with sealing device into polished receiving socket of packer of shank tail, and coil-tubing unit is installed. Test HFF is performed in the interval from the shoe of the column to the first disconnected packer. Test HFF results in the basic HFF in the given interval. In subsequent intervals HFF is carried out similarly. Number of cycles is equal to the number of the formation fracturing ports. After closing the last port, flow regulators are opened.EFFECT: higher efficiency of hydrocarbon production due to selective production of HFF, increased area of hydrocarbon influx due to devices of flow regulators and prevention of proppant transport.1 cl, 1 dwg

Description

FIELD OF THE INVENTION

The invention relates to the oil and gas industry, in particular to the development of oil, gas and gas condensate fields and can be used for opening productive formations by conducting interval hydraulic fracturing and equipment at these intervals with filters when completing well construction.

State of the art

A known method of developing wells with a liner, including continuous casing, divided into sections by annular packers and circulation ports installed on each of the sections (product catalog of JSC OKB Zenit "Well equipment → Equipment for hydraulic fracturing with a hydro-mechanical packer." Electronic resource www.zenith .ru).

The disadvantages of well development using well-known designs include the following:

- the absence of a filter element that prevents the destruction of the bottom-hole zone of the reservoir and the ingress of sand and other mechanical impurities into the well, including the necessary requirements to prevent proppant removal are not provided, as a result of which the rock cracks gradually close, thereby deteriorating the efficiency of hydrocarbon production after work to intensify the influx;

- the area of inflow of the reservoir product is limited by the openings of the circulation ports.

A well-known design of the well for conducting multi-stage hydraulic fracturing (PM No. 175464), including a cementless liner for conducting multi-stage hydraulic fracturing (hydraulic fracturing), characterized in that it is made with the possibility of placement in the reservoir, fixing in the production casing and separation of annular packers into sections containing a section of filter pipes, a section of solid pipes and controlled circulation couplings with the possibility of opening and closing, while the width of the slit in the filter pipe is determined by the ratio t≤ (0,65 ÷ 0,80) D10,

where t is the width of the slit in the filter pipe, mm;

D ₁₀ - the particle diameter of the proppant for hydraulic fracturing, corresponding to the size of the mesh through which 10% of the total mass of the proppant material passes, mm.

This design, including a filter pipe with a filter slit width determined by the stated ratio, is aimed at preventing proppant from being taken out of hydraulic fractures into the well.

The disadvantage of this design is that for hydraulic fracturing, a tubing string equipped with a dual packer is required, which implies the appearance of additional flow resistance, this will entail a decrease in proppant concentration and, accordingly, a hydraulic fracture will not be effective enough. Also, it is not possible to control the fixation of the upper packer, and the lower packer cannot be crimped properly, i.e. there is a high probability of a packer leak during hydraulic fracturing, which will lead to proppant precipitation into the column.

The closest in technical essence and the achieved result is a method of completing the construction of a producing horizontal well by conducting an interval hydraulic fracturing (patent RU No. 2564316), including drilling a trunk of a producing horizontal well with determining the reservoir properties of the formation and their changes along the horizontal wellbore, splitting the trunk wells for zones differing in reservoir properties by a factor of 1.5-1.6, selection of the throughput of the filter holes for each zone and the number of holes depending on the filtration and reservoir characteristics, descent of a production drill string with a filter into the trunk of a drilled horizontal well and annular oil-swellable packers, placement of packers at the borders of zones with different filtration-capacitive characteristics, fixing the production string, lowering the pipe string with the pump into the horizontal well and launching the horizontal wells in operation. According to the invention, a water swellable packer is installed on the outer surface of each filter, made in the form of an elastic sleeve with holes and stretched onto the filter, the holes in the filters being aligned with the holes made in the elastic sleeves, and the diameters of the holes in the elastic sleeve are twice as large as the diameters of the holes in the filters and when in contact with water, the holes in the elastic sleeve are pulled together and hermetically block the holes in the filters from the outside, the pipe string is disconnected from the retractable liner plugged from below by triggering the downhole disconnector, and then the pipe string is removed to the surface.

The disadvantages of this method are:

- swelling packers and hoses require a certain dwell time for their activation or deactivation (in the case of hoses), the reliability of which in reservoir conditions is doubtful and it is almost impossible to control the result;

- the length of the zones separated by annular packers for the selective production of hydraulic fracturing is very limited, since, for example, at a 100 m zone it will be impossible to isolate one sleeve (close the holes) and leave the others, in addition, the sleeve will have to withstand the pressure created during hydraulic fracturing;

- low efficiency, due to the fact that this method has not implemented measures to prevent proppant removal during well operation.

The proposed method for completing the construction of a production well with a horizontal end of the barrel is aimed at eliminating the disadvantages of the known methods.

Disclosure of the invention

The technical result, the implementation of which the claimed technical solution is directed, is to increase the efficiency of field development and a more complete extraction of hydrocarbons from productive formations due to the selective production of hydraulic fracturing, including repeated if necessary, as well as an increase in the zone of influx of hydrocarbons through the use of flow control devices and the effective prevention of proppant removal.

The problem is solved by the method of completing the construction of a production well with a horizontal end of the well, including drilling a horizontal well with determining the reservoir properties of the reservoir according to the results of geophysical studies, lowering and securing the production string to the beginning of the horizontal section of the well, lowering and installing an uncemented liner in the horizontal end of the well filter, conducting interval hydraulic fracturing.

The technical result is achieved due to the fact that they carry out the launch and installation of a cementless shank-filter (Fig.) With ports of multi-stage hydraulic fracturing 1, 2, 3, 4, 5, filters with flow controllers 6, disconnecting packers 7, then run the columns tubing with a complex of underground equipment to the design depth, a column of tubing with a sealing device on the lower pipe is inserted into the polished receiving socket of the liner suspension packer, installation of a coiled tubing installation and preparatory work is carried out before the production of hydraulic fracturing (hydraulic fracturing) then test hydraulic fracturing is performed in the interval from the shoe of the column to the first uncoupling packer, and according to the test hydraulic fracturing, the main hydraulic fracturing is performed in this interval, then the port of multi-stage hydraulic fracturing is closed, port 2 is opened, and hydraulic fracturing is started in the next interval , similar work is carried out with subsequent ports 3, 4, 5: closing the previous port, opening the next one and producing hydraulic fracturing in the next interval, the number of hydraulic fracturing cycles being equal to the number of ports of multistage hydraulic fracturing, then after closing the last port of multistage hydraulic fracturing flow controllers 6, allowing to increase the zone of formation fluid inflow, dismantle the hydraulic fracturing equipment and begin to develop the well.

Thus, the technical result achieved using the claimed invention provides:

- the ability to selectively process selected intervals;

- increase in the zone of formation fluid inflow due to the devices of flow regulators;

- change of the complex of underground equipment without large volumes of killing wells;

- reliable isolation of filters during hydraulic fracturing operations;

- the possibility of repeated hydraulic fracturing in case of a drop in productivity;

- due to the absence of a drilling / milling operation, eliminating the risk of accumulation of metal residues at the bottom;

- preventing the destruction of the bottom-hole zone of the reservoir and the ingress of sand and other mechanical impurities into the well through the filter element.

Brief Description of the Drawings

The drawing shows a cementless shank filter with a layout for multi-stage hydraulic fracturing with controlled ports and flow control devices, where

1 - port multi-stage hydraulic fracturing number 1,

2 - port multi-stage hydraulic fracturing number 2,

3 - port multi-stage hydraulic fracturing number 3,

4 - port multi-stage hydraulic fracturing number 4,

5 - port multi-stage hydraulic fracturing number 5,

6 - filter with a device for flow control,

7 - uncoupling packer. The implementation of the invention

Launching and fixing the production casing is carried out before the start of the horizontal section of the barrel. In the process of drilling a horizontal wellbore, the reservoir properties of the formation are determined by the results of geophysical studies. Make a descent and installation in the horizontal end of the barrel of the cementless filter shank, which includes the following main elements shown in the figure.

- managed ports of multi-stage hydraulic fracturing 1, 2, 3, 4, 5;

- filters with flow regulator 6;

- uncoupling packers 7 hydraulic or swelling;

- a polished receiving socket for the liner suspension packer (not shown) for the stinger connection with the complex of underground equipment.

A column of tubing with a complex of underground equipment is lowered to the design depth. A column of tubing is inserted with a sealing device on the lower pipe (stinger) into the receiving socket of the liner suspension packer and landing by unloading. They carry out work on the installation of a coiled tubing installation and piping of the mouth. Conduct preparatory work before the production of hydraulic fracturing. A switching tool is activated on the sleeveless long pipe, activated by the hydraulic pressure in the sleeveless long pipe, which moves the sliding sleeve of port number 1 of the multi-stage hydraulic fracture to the open position. The opening of the port is checked by the presence of the injectivity of the well through it. Make the rise of the switching tool from the well.

A portion of proppant and hydraulic fracturing fluids is injected in a volume of up to one ton (test hydraulic fracturing) into the lower zone isolated by packers 7, the pressure and flow rate of proppant and fluid are recorded, the results are processed and the design of the main hydraulic fracturing is corrected (proppant volume, optimal flow rate) when downloading, etc.). In accordance with the adjusted plan, the main hydraulic fracturing is carried out. At the end of the recording of hydraulic fracturing parameters and the discharge of the well after hydraulic fracturing in the first interval, a sleeveless long pipe with a flushing nozzle and a switching tool is lowered. The proppant remaining in the shank cavity is washed out. The multi-stage hydraulic fracture port 1 closes with the switching tool.

Next, the switch tool is moved to the installation depth of the next multi-stage hydraulic fracture port number 2, the port is opened and hydraulic fracturing production is performed, then, with the lowering of the switching tool, the multi-stage hydraulic fracture port is closed 2. For the next intervals, hydraulic fracturing is carried out similarly, with the number of work cycles in hydraulic fracturing is equal to the number of multistage hydraulic fracture ports (multistage hydraulic fracture ports 3, 4, 5), after closing the last multistage hydraulic fracture port with switching tool on a sleeveless long pipe, flow regulators 6 are opened, the sleeveless long pipe is raised, hydraulic fracturing equipment is removed and begin to develop the well.

Claims (1)

A method of completing the construction of a production well with a horizontal end of the wellbore, including drilling a horizontal wellbore with determining the reservoir properties of the reservoir according to the results of geophysical studies, lowering and securing the production string to the beginning of the horizontal section of the wellbore, lowering and installing an uncemented filter liner in the horizontal end of the wellbore, conducting interval hydraulic fracturing, characterized in that the cement-free filter liner is run and installed with uncoupling packers, multi-stage hydraulic fracturing ports, flow controllers, then the tubing string with the complex of underground equipment is lowered to the design depth, the string is introduced tubing with a sealing device on the lower pipe into the polished receiving socket of the liner suspension packer, the coiled tubing installation and preparatory work are carried out bots before the production of hydraulic fracturing (Fracturing), then they produce test hydraulic fracturing in the interval from the shoe of the column to the first uncoupling packer, and according to the results of the test hydraulic fracturing, the main hydraulic fracturing is performed in this interval, then in subsequent intervals hydraulic fracturing is carried out similarly, with the number of work cycles according to hydraulic fracturing is equal to the number of ports of multistage hydraulic fracturing, then after closing the last port of multistage hydraulic fracturing, flow controllers are opened.

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