RU2726685C1 - Pulsed hydraulic fracturing method - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: present invention relates to mining and can be used for development and restoration of production well flow, which decreased as a result of colmatation of bottom-hole zone with asphalt-resin-paraffin formations and mechanical additives. Method involves generation of periodic pressure pulses in the bottomhole zone in the form of a wave moving in the well cavity formed at periodical increase of pressure in the well by connection to the first and the second sources of liquid under pressure. During hydraulic fracturing preliminary time of movement of liquid mass movement wave from wellhead to bottom-hole zone and duration of expansion and closure of formation cracks is established, initial pressure is installed in cavity of well, wherein fractures of formation are closed, then valves are opened for time, during which wave of movement of mass of liquid reaches bottom-hole zone and acts on fractures of formation. Then the valves are closed for the period of pressure reduction in the well to the value of the initial one, to the lines connecting the liquid filling valves with sources of liquid under pressure, hydropneumatic accumulators are connected. Permissible pressure created in the column head of the well, source of fluid under pressure is determined, and hydropneumatic accumulators are connected to the annular space of the well through one of gate valves of the cross piece, the gate valve is closed on the opposite side of the cross-piece. Well annular space is filled with fluid up to wellhead, plunger of pump-rocking pump is changed to position that minimizes possibility of pump damage at pressure drops, hydropneumatic accumulators are filled with liquid till pressure does not exceed permissible pressure in the column head of the well.

EFFECT: impulse-wave treatment of bottom-hole zone through annular space without extraction of submersible equipment.

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Description

The proposed invention relates to mining and can be used to develop and restore the flow rate of production wells, which decreased due to clogging of the bottomhole zone with asphalt-resin-paraffin formations and mechanical impurities.

There is a known method of treatment of the bottomhole zone of a well (patent No. 2344281, publ. 2007.05.14), including the formation of a depression pressure drop between the bottomhole zone and the well cavity by creating periodic pressure pulses in the bottomhole zone in the form of a wave moving along the well cavity, while pre-connecting the wellhead with a receiver filled with gas, the liquid drain valve is opened when the well fluid moves from the bottom hole to the wellhead at a frequency that ensures the buildup of its mass in the resonance mode.

However, a receiver filled with gas is used to reciprocate the wellbore fluid column. The receiver is not designed to store energy and generate shockwaves.

There is a known method for treating the near-wellbore zone of the formation (patent No. 2392425, publ. 2010.06.20), in the implementation of which the time of movement of the wave of movement of the mass of liquid from the wellhead to the bottomhole zone and the duration of expansion and closure of the formation cracks are preliminarily estimated, the initial pressure is set in the well where the formation cracks are closed, then the fluid filling valve is opened for a time during which the wave of fluid mass movement reaches the bottomhole zone and acts on the formation fractures, then the fluid filling valve is closed and the fluid drain valve is opened to reduce the pressure in the well to the initial value.

However, since a pumping unit is most often used as a pressure source, when the topping-up valve is opened, the pressure in the well after a short high-pressure pulse drops sharply. The wave of movement of the wellbore fluid upon reaching the bottom does not have time to open and deform the formation cracks.

A known method of implementing impulse hydraulic fracturing (patent No. 2586693, publ. 2016.06.10), including the formation of pressure drops between the bottomhole zone and the well cavity by creating a wave of movement of the fluid mass moving along the well cavity, in which the time of movement of the wave of movement of the fluid mass from the wellhead is preliminarily estimated to the bottomhole zone and the duration of the expansion and closure of the formation cracks, set the initial pressure in the well cavity, at which the formation cracks are closed, then the fluid filling valve is opened for the time during which the wave of fluid mass movement reaches the bottomhole zone and acts on the formation cracks, then close the valve for adding liquid and open the valve for draining the liquid to reduce the pressure in the well to the initial value, a hydraulic-pneumatic accumulator is connected to the line connecting the valve topping up the liquid and the source of the liquid under pressure, the volume of which is determined by the flow rate of the injected liquid.

However, when processing deep wells, a powerful pressure pulse is required at the bottom of the wells and its duration is sufficient to deform the formation fractures.

There is a known method of impulse hydraulic fracturing (patent No. 2644368, publ. 2018.02.09), taken as a prototype, including the formation of periodic pressure pulses in the bottomhole zone in the form of a wave moving through the well cavity, generated by a periodic increase in pressure in the well by connecting with the first and second sources of fluid under pressure using the first and second valves, during hydraulic fracturing, the time of movement of the wave of movement of the fluid mass from the wellhead to the bottomhole zone and the duration of expansion and closure of formation fractures are preliminarily estimated, the initial pressure is set in the well cavity at which the formation fractures are closed, then sequentially after a period of time, ensuring the formation of a total pressure pulse at the bottom of the well, the valves are opened, then the valves are closed for the period of decreasing the pressure in the well to the initial value, to the lines connecting the valves for adding liquid to the sources of Hydro-pneumatic accumulators are connected under pressure, the volume of which is determined by the flow rate of the well fluid when it flows into the formation.

However, in order to treat the well through the tubing, it is necessary to carry out trips to retrieve the downhole equipment.

The objective of the invention is to conduct a pulse-wave treatment of the bottomhole zone of the well through the annulus without removing the downhole equipment.

The problem is solved by the fact that, using a method for performing pulsed hydraulic fracturing, including pumping liquid into the wellbore cavity, generating periodic pressure pulses in the bottomhole zone in the form of a wave moving along the wellbore cavity, which is generated during periodic pressure increase in the well by connecting to the first and second sources of liquid, under pressure, during hydraulic fracturing, the time of movement of the wave of motion of the fluid mass from the wellhead to the bottomhole zone and the duration of the expansion and closure of formation fractures are preliminarily estimated, the initial pressure is set in the well cavity at which the formation fractures are closed, then the valves are opened for the time during which the wave of movement of the fluid mass reaches the bottomhole zone and acts on the formation fractures, then the valves are closed for the period of reducing the pressure in the well to the initial value, to the lines connecting the valves of the liquid topping up with the sources of fluid under pressure s hydraulic accumulators, the volume of which is determined by the flow rate of the well fluid when it flows into the formation, determine the allowable pressure created in the wellhead, the source of the fluid under pressure, and the hydraulic accumulators are connected to the annular space of the well through one of the cross valves, block the valve on the opposite side crosses, fill the annular space of the well with liquid to the wellhead, move the pump pump plunger to a position that minimizes the possibility of damage to the pump due to pressure drops, the hydraulic pneumatic accumulators are filled with liquid to a pressure not exceeding the permissible pressure in the column head of the well.

This method allows the formation of high-pressure zones in the casing head of the well, which move through the annulus to the bottom-hole zone and, due to the addition of wave amplitudes, form a pressure drop in the perforation zone sufficient for the development of fractures.

The hydro-pneumatic accumulator is a metal cylindrical body filled with gas (usually nitrogen, placed in a bladder). When a liquid is pumped into a hydraulic-pneumatic accumulator, the gas is compressed, due to which the hydraulic-pneumatic accumulator can serve as an energy storage device.

The method is implemented as follows. The valves are connected to the annular space of the well through the valve of the cross, the first of which connects the well cavity with the first hydropneumatic accumulator, the second - the well cavity with the second hydropneumatic accumulator. Both hydropneumatic accumulators have the ability to independently fill with liquid up to a given pressure. The well is filled with fluid to the initial pressure level at which the formation fractures are closed. Hydropneumatic accumulators are required to maintain fluid pressure in the well for a given period of time. The fluid is pumped into the well to the initial pressure level at which the formation fractures are closed. The pump pump plunger is moved to a position that minimizes the possibility of damage to the pump due to pressure drops, the hydraulic pneumatic accumulators are filled with liquid up to a pressure not exceeding the permissible pressure in the well string.

At the moment of opening one of the valves in the annulus, a high pressure region is formed, which moves to the bottomhole zone and sets the well fluid in motion. Through the filling valve into the well cavity, the liquid enters not only from the source of liquid under pressure, but also from the hydraulic pneumatic accumulator, which increases the duration of the pressure pulse.

Under the influence of pressure applied to the wellhead, the velocity of the mass of the wellbore fluid increases. When the sump of the well is reached, the wave of fluid movement rests against an obstacle and sharply slows down, which is accompanied by an increase in pressure.

After a time interval determined by the geological and physical characteristics, the second valve is opened. An additional high pressure area forms at the wellhead, which moves to the bottomhole zone and sets the well fluid in motion. The formed shock wave reaches the sump and is added to the reflected first shock wave. By adjusting the time interval between the first and second waves at the bottomhole, a pulse of increased amplitude is created without increasing the pressure at the wellhead, or a long pulse is generated.

When the pressure pulse is transmitted through the annulus, the wave attenuation is less than when transmitted through the tubing, in proportion to the larger cross-section.

An increase in pressure in the near-wellbore zone leads to the expansion of existing fractures and the formation of new ones. The movement of the fluid mass in the bottomhole zone contributes to its washing, the separation of adsorption deposits from the walls of pore channels and cracks, as well as loosening and spalling of low-permeability fragments of the formation skeleton.

After a period of time sufficient for the formation of new formation fractures, the valves are closed, which is accompanied by a decrease in pressure in the bottomhole zone. When the initial pressure is reached, the formation fractures are closed. The operation of the pulse pressure increase in the bottomhole zone is repeated the required number of times. With regular deformation, cracks develop due to fatigue failure.

The movement of a multi-ton mass of fluid affects both the bottomhole zone and the formation mass. Infra-low frequencies have low attenuation, therefore, periodic changes in bottomhole pressure are transmitted in the form of low-frequency waves along the strike of formations and contributes to the redistribution of stresses in the massif, which has a positive effect on oil recovery.

Pulse fracturing technology allows creating a network of fractures in the near-wellbore zone of the formation, diverging from the fracture bore. The main result is an increase in the effective radius of the well, the involvement of the entire stratum in the development, the involvement of the maximum number of productive layers and remote areas. With impulse hydraulic fracturing, the flow rate is low. Creation of a network of fractures promotes uniform "loosening" of the near-wellbore zone of the formation.

Wellbore fluid may contain chemicals for more productive treatment. The method can be applied in conjunction with other types of treatment of the bottomhole zone: acidic, thermal, acoustic, etc.

Claims (1)

A method for carrying out pulsed hydraulic fracturing, including pumping liquid into the wellbore cavity, generating periodic pressure pulses in the near-wellbore zone in the form of a wave moving along the wellbore cavity, generated during periodic pressure increase in the well by connecting to the first and second sources of pressurized fluid during hydraulic fracturing the time of movement of the wave of movement of the fluid mass from the wellhead to the bottomhole zone and the duration of the expansion and closure of the formation cracks are preliminarily estimated, the initial pressure is set in the well cavity at which the formation cracks are closed, then the valves are opened for the time during which the wave of movement of the fluid mass reaches the bottomhole zone and acts on the formation fractures, then the valves are closed for the period of decreasing the pressure in the well to the initial value, hydraulic accumulators are connected to the lines connecting the valves of the fluid addition to the sources of fluid under pressure, the volume of which which is determined by the flow rate of the borehole fluid when it flows into the formation, characterized in that the allowable pressure created in the casing head of the well is determined, the source of the fluid under pressure, and the hydro-pneumatic accumulators are connected to the annulus of the well through one of the cross valves, shut off the valve on the opposite side crosses, fill the annular space of the well with liquid to the wellhead, move the pump pump plunger to a position that minimizes the possibility of damage to the pump due to pressure drops, the hydraulic pneumatic accumulators are filled with liquid to a pressure not exceeding the permissible pressure in the column head of the well.