RU2400623C2 - Well flow rate increasing method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: flow rate increasing method of oil and gas wells consists in the fact that all productive formations of the well are brought into simultaneous operation. For that purpose, the well is drilled to one formation, offshoots are drilled, and in case of lower formations the well is drilled ahead, and annular space in the zone of formations is cemented. Secondary drilling of all formations is performed. Prior to the beginning of production, there installed are geophysical instruments in the zone of each drilled formation. Fluid level in the well is smoothly decreased by swabbing or by means of jet pump; then instruments are removed and as per their readings there determined are values of bottom-hole pressures in wells, at which formations are brought into operation. As per the same data there determined are formations subject to formation cross flows, and the latter are eliminated. Then geophysical instruments are again installed in the zone of each formation, and a jet pump is lowered to the well to design depth. During the repair period of jet pump there analysed are readings of geophysical instruments, and if formation cross flows are detected due to production of formations, formation cross flows are eliminated. Jet pump is lowered again and production is continued with the specified repetition of repair periods and with elimination of formation cross flows.

EFFECT: increasing production efficiency of oil and gas owing to shifting single-formation wells to multiple-formation production and detection and elimination of cross flows prior to production.

Description

The invention relates to the oil and gas industry and can be used to dramatically increase the flow rate of a well, which ensures the doubling of oil and gas production in the country in a short period of time with minimal cost, mainly due to the transfer of existing single-layer wells to a multilayer category.

There are various ways to increase the flow rate of wells by performing various geological and technical measures to influence the reservoir (EI Bukhalenko, VE Bukhalenko. Equipment and tools for repairing wells. M., Nedra, 1991).

A disadvantage of the known methods is that they do not provide a sufficient increase in flow rate. In the best case, the flow rate increases by only a few percent, but most often by tenths of a percent.

This disadvantage is eliminated in another known method (A.I. Ipatov, M.I. Kremenetsky. Geophysical and hydrodynamic control of the development of hydrocarbon deposits. M., 2005, p.219-224).

The method consists in opening and operating in the well several layers at once.

The production rate of multilayer wells increases several times in comparison with wells that operate only one layer.

It would seem that unprecedented prospects for increasing the flow rate of wells and increasing volumes of oil and gas are opening up.

However, in practice, it turned out that multilayer wells have a strategic drawback, because of which government environmental authorities prohibit multilayer production until this drawback is eliminated.

The disadvantage is that with the simultaneous operation of several layers in the well, reservoir flows always occur (Diyashev R.N. Study of the effectiveness of the joint and separate development of heterogeneous oil-saturated reservoirs of multilayer oil fields. - Karotazhnik, No. 109, 2003, p. 141-166 )

The flows are due to the fact that the reservoir pressures in each individual reservoir are different from each other, as a result of which the fluid from the reservoirs with a higher reservoir pressure passes into the reservoirs with a lower reservoir pressure. This results in losses in both production and production rates.

Due to this drawback, drilled multilayer wells are in trial operation and research is being conducted on them to find methods for eliminating reservoir flows.

However, it turned out that research in the production process without prior development of the well does not allow us to determine the bottomhole pressure at which each specific formation is included in the work and begins to produce fluid into the well. Having no data on the magnitude of these bottomhole pressures, there is no way to develop geological and technical measures that would ensure the complete elimination of reservoir flows.

The above drawback is so strategic that it does not allow to open a new direction for a qualitative increase in oil and gas production in the country.

This new direction follows from the fact that by drilling new multilayer wells, even if it is possible to reliably eliminate reservoir flows in the future, it is impossible to quickly increase production in the country due to the high cost of time and money for the construction of such wells.

A new direction for a sharp and qualitative increase in oil and gas production would be the rapid commissioning of all productive formations intersected by the wellbore in existing wells that operate in only one productive stratum, although the well passes through several strata.

However, it is possible to start using this new direction again only if it is possible to know before the start of production the values of the bottomhole pressures of the reservoirs, at which the reservoirs are turned on and begin to deliver fluid to the well. Based on this information, it will be possible to develop geological and technical measures that reliably eliminate reservoir flows in multilayer wells prior to production. This direction can be used primarily in existing wells, which are not difficult to transfer to multi-layer production due to the multiple cost reduction compared to the construction of new multi-layer wells.

The objective of the invention is to eliminate the above drawbacks of existing multilayer wells and creating a new direction for a sharp and qualitative increase in oil and gas production due to the transfer of existing single-layer wells to multilayer production.

The technical result achieved by using the proposed invention is the possibility of developing geological and technical measures to identify and eliminate reservoir flows in multilayer wells before production, and providing on this basis the opportunity to open a new direction of a sharp and qualitative increase in oil and gas production due to transfer of existing single-layer wells to multi-layer production.

The specified technical result is achieved by the fact that in the method of increasing the production rate of oil and gas wells, namely, all productive strata of the well are put into simultaneous operation, for which the well is drilled to one stratum, sidetracks are drilled, and in the presence of underlying strata, the well is drilled, cement the annulus in the zone of the strata, perform a secondary opening of all the strata, install geophysical instruments in the zone of each opened stratum before the start of production, smoothly lower the liquid level and in the well by swabbing or using a jet pump, then the devices are removed and their readings determine the bottomhole pressure in the wells at which the formations are included in the work, using the same data, formations that are prone to formation overflows are eliminated, the overflows are eliminated, and then the geophysical instruments are installed again in the zone of each layer, the jet production pump is lowered into the well to the calculated depth, during the repair period of the jet production pump, the readings of geophysical instruments are analyzed and when formation retokov due to generation layers eliminate reservoir flows again lowered a jet pump mining and extraction continued with said repetition periods of repair and removal of the reservoir overflows.

Introduction to the simultaneous operation of all productive formations provides a new direction for a sharp and qualitative increase in oil and gas production due to the ability to quickly transfer existing wells to multilayer production at a relatively low cost compared to the very large cost of time and money for the construction of new multilayer wells.

The fact that the wells are drilled to one formation, the sidetracks are drilled, and in the presence of the underlying layers, the well is drilled, the annulus is cemented in the formation zone, it allows the preparation of all the formations if any difficulties and shortcomings occur that do not allow high-quality input of individual layers into operation without modifications. However, as a rule, all the layers must be cemented in a quality manner during the construction of a single-layer well and access must be available to allow secondary opening of all the layers without any additional costs.

Secondary opening of all layers provides a rapid increase in oil and gas production. In modern conditions, the secondary opening of formations is performed, as a rule, by explosive cumulative perforators, which provide opening in a very short period of time.

The fact that before the start of production geophysical instruments are installed in the area of each discovered reservoir allows one to identify and eliminate reservoir flows before the start of production, which will allow obtaining permission from government bodies to operate multilayer wells, which guarantee the absence of reservoir flows.

A smooth lowering of the liquid level in the well by swabbing or using a jet pump makes it possible to detect bottomhole pressures and other parameters of the fluid at which each individual formation is turned on and starts to deliver fluid to the well. This information makes it possible to identify formations prone to formation overflows, and then develop specific measures to eliminate overflows. In contrast, in the existing method of multilayer production without prior development of the well, there is a sharp decrease in the liquid level after turning on the production pump, which does not allow geophysical instruments to have time to fix the inclusion of each individual formation.

Removing devices from the well and determining, based on their testimony, the bottomhole pressure in the wells at which the formations are included in the work, provides information for determining the order in which the strata are put into operation and the bottomhole pressure at which each individual stratum is included in the work. In this case, it becomes possible to identify formations that are susceptible to formation overflows.

The determination of formations prone to reservoir overflows allows the development and implementation of geological and technical measures to ensure the elimination of identified reservoir overflows, which is provided for in the invention.

The re-installation of geophysical instruments in the area of each formation before the start of production allows you to control the behavior of the layers and the possible occurrence of overflows in the production process, when the characteristics of the layers change during their production.

The descent into the well at the estimated depth of the jet production pump allows the production of oil and gas from a multilayer well with a guarantee of the absence of reservoir flows.

The choice of a jet pump as a production pump that is neutral to the gases released from the working formations, resulting in water hammer and spacing of electric centrifugal pumps, allows to increase the installation depth of the production pump, which allows to reduce downhole pressure and eliminate formation flows, although an increase in discharge will be observed from gas strata to which the jet pump is insensitive (neutral).

Analysis of the readings of geophysical instruments recorded during the production process, performed during the repair period of the jet production pump, makes it possible to identify reservoir flows due to reservoir formation.

The identification of reservoir flows makes it possible to develop and carry out geological and technical measures to eliminate reservoir flows during the production process.

Continuous analysis of the readings of geophysical instruments during the repair periods of the jet production pump allows timely identification of emerging reservoir flows and timely implementation of the necessary geological and technical measures to eliminate identified flows.

The proposed method does not require its graphic image.

The proposed method is carried out in the following order: first, all productive formations are brought into simultaneous operation, for which wells are drilled to one formation, sidetracks are drilled, and if there are underlying layers, the well is drilled, the annulus is cemented in the formation zone. Next, perform a secondary opening of all layers. Geophysical instruments are installed in the area of each open reservoir before production begins to control fluid parameters. All reservoir studies, identification and elimination of reservoir flows are performed prior to production in the process of well development by geophysical enterprises. This allows oil and gas to be produced with previously eliminated reservoir flows. Government bodies now have every reason to allow the transfer of all existing single-layer wells to multi-layer production, which will dramatically and at low cost increase oil and gas production in the country.

The ability to conduct research with the subsequent elimination of reservoir flows by geophysical enterprises prior to production is due to the fact that geophysical enterprises simulate the production process by gradually lowering the liquid level in the well, in which formations are gradually included in the work.

Perform a smooth lowering of the fluid level in the well by swabbing or using a jet production pump.

The production pump is chosen for a special one that is not afraid of the gas factor while lowering the liquid level in the well to eliminate reservoir flows and to improve the well flow rate and pump performance.

As such a pump, a jet pump is used.

This makes it possible to transfer single-layer wells to multi-layer and conduct continuous monitoring of wells to ensure a qualitative increase in oil and gas production in the absence of reservoir flows.

Next, remove the appliances. The bottomhole pressures in the wells at which the formations are included in the work are determined from their readings, and the formations that are subject to formation overflows are also determined. Eliminate overflows. Then again install geophysical instruments in the area of each layer. A jet production pump is lowered into the well to a calculated depth and oil and gas are extracted from a multilayer well with a guarantee that there will be no formation flows.

Further, in the repair period of the jet production pump, the readings of geophysical instruments are analyzed. Identify reservoir flows due to the development of reservoirs. Eliminate reservoir flows. Then lower the jet production pump and continue production with the specified repetition of repair periods and with the elimination of reservoir flows.

The translation of the fleet of single-layer wells into multi-layer is performed as follows. If we assume that during the operation of an average of 5 formations in each well, the production rate of each well will increase by an average of 4 times, then to increase the production by 2 times in 10 years, it will be necessary to transfer half (50%) of single-layer wells over this period to multilayer production . Annually, 5% of single-layer wells will need to be transferred to multilayer production. Such a task is feasible if we put about 10 teams in each large oil and gas company to solve it.

There is no other option in the country to double the volume of oil and gas production in 10 years, moreover, with relatively small expenditures of funds, except for the proposed method.

Claims (1)

A method of increasing the production rate of oil and gas wells, which consists in the fact that all productive strata of the well are put into simultaneous operation, for which the well is drilled to one stratum, sidetracks are drilled, and if there are underlying strata, the well is drilled, the annulus is cemented in the stratum zone, and secondary opening of all reservoirs, before the start of production, geophysical instruments are installed in the zone of each discovered reservoir, smoothly lower the liquid level in the well by swabbing or using a jet pump and, then the devices are removed and their readings determine the bottomhole pressure in the wells at which the formations are included in the work, according to the same data, formations that are prone to formation overflows are determined, the overflows are eliminated, then geophysical instruments are installed again in the area of each formation, and lowered into the well at the calculated depth, the jet production pump, during the repair period of the jet production pump, the readings of geophysical instruments are analyzed and, when formation flows are detected due to formation formation, the formation is eliminated oki, they again lower the jet production pump and continue production with the indicated repetition of repair periods and with the elimination of reservoir flows.