RU2776266C1 - Method for implementing pulsed hydraulic fracturing - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining and can be used for the development and restoration of production wells. The method includes pumping fluid into the well cavity, generating periodic pressure pulses in the bottomhole zone in the form of a wave moving along the well cavity, which is formed during a periodic increase in pressure in the well, using 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 closing of the formation fractures are preliminarily estimated, the initial pressure is set in the well cavity at which the formation fractures are closed, then the first valve is opened for the time during which the movement wave mass of fluid reaches the bottomhole zone and acts on the formation fractures, then the first valve is closed and the second valve is opened to reduce the pressure in the well to the initial value. The opening of the second valve is carried out after a period of time and at a speed that ensures the removal of colmatants. A hydropneumatic accumulator is connected to the line connecting the first valve and the source of liquid under pressure. To form a pressure pulse in the bottomhole zone, the first valve is closed when the speed of movement into the well decreases after the first valve is opened. To form fluid flows in the bottomhole zone, the first valve is closed at the highest velocity of fluid movement into the well after the first valve is opened.

EFFECT: alternation of pressure pulses is provided to create and develop a network of fractures in the bottomhole zone, as well as counter-parallel fluid flows for washing out and carrying out clogging deposits from the formation into the well cavity.

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Description

SUBSTANCE: invention relates to mining and can be used for development and restoration of production wells flow rate, which has decreased due to clogging of the bottomhole zone with asphalt, resin, and paraffin formations and mechanical impurities.

There is a known method for treating the near-wellbore formation zone (patent No. 2266404, publ. 2005.12.20), including the creation of periodic pressure pulses in the near-wellbore zone of the formation in the form of a shock wave moving along the well cavity, which is formed when the well cavity is periodically opened at the wellhead using valves, one of which connects the cavity of the well with a drain tank, the second - with a source of fluid under pressure.

However, the bottomhole zone is poorly flushed with well fluid, since the hydraulic shock has a short exposure time, during which the formation fractures do not have time to fully open and close during the impact.

A method for treating the bottomhole zone of a well (patent No. 2344281, publ. 2007.05.14), including the formation of a depression differential pressure 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 preliminarily connecting the wellhead with a receiver filled with gas, the liquid drain valve is opened when the well fluid moves from the bottom to the wellhead with a frequency that ensures the buildup of its mass in the resonance mode.

However, a receiver filled with gas is used to reciprocate the downhole fluid column. The receiver is not designed to store energy and form a shock wave.

There is a known method for treating the near-wellbore formation zone (patent No. 2392425, publ. 2010.06.20), during which 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 in which the formation fractures are closed, then the liquid filling valve is opened for the time during which the wave of movement of the liquid mass reaches the bottomhole zone and acts on the formation fractures, then the liquid filling valve is closed and the liquid 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 top-up valve is opened, the pressure in the well drops sharply after a short-term high-pressure pulse. The wave of movement of the well fluid when reaching the bottom does not have time to open and deform the formation fractures.

There is a known method for implementing pulse 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 periodic pressure pulses in the bottomhole zone in the form of a wave of movement of the fluid mass moving along the well cavity, at which the the time of movement of the fluid mass movement wave from the wellhead to the bottomhole zone and the duration of expansion and closing of the formation cracks, set the initial pressure in the well cavity at which the formation fractures are closed, then the liquid top-up valve is opened for the time during which the fluid mass movement wave reaches the bottomhole zone and acts on the fractures of the formation, then close the liquid top-up valve and open the liquid drain valve to reduce the pressure in the well to the initial value, a hydropneumatic accumulator is connected to the line connecting the liquid top-up valve and the source of liquid under pressure, the volume to which is determined by the flow rate of the injected liquid.

However, the method makes it possible to generate an impulse directed in one direction for filling and opening cracks. For effective fracturing, it is necessary to alternate the direction of the pressure pulse, in order to deform, loosen, chip fragments of the formation skeleton, to develop a network of cracks.

There is a known method for implementing pulse hydraulic fracturing (patent No. 2737632, publ. 2020.12.01), taken as a prototype, including the formation of pressure drops between the bottomhole zone and the well cavity by creating periodic pressure pulses in the bottomhole zone in the form of a wave of fluid mass moving along the well cavity, at which the time of movement of the wave of movement of the mass of fluid from the wellhead to the bottomhole zone and the duration of the expansion and closing of the formation fractures are preliminarily estimated, the initial pressure is set in the well cavity at which the formation fractures are closed, then the liquid top-up valve is opened for the time during which the movement wave mass of fluid reaches the bottomhole zone and develops formation fractures, then close the fluid top-up valve and open the fluid drain valve to reduce the pressure in the well to the initial value, the second valve is opened after a period of time and at a speed necessary to remove colmatants and m mechanical destruction of the formation skeleton, a hydropneumatic accumulator is connected to the line connecting the liquid topping valve and the source of liquid under pressure, the volume of which is determined by the flow rate of the injected liquid.

However, effective treatment of the bottomhole zone requires both the creation of pressure drops to form a network of fractures, and the formation of alternating multidirectional fluid flows to wash out the bridging agents of the bottomhole zone, destroy and remove deposits.

The objective of the invention is the alternation of pressure pulses for creating and developing a network of fractures in the bottomhole zone, as well as counter-parallel fluid flows for washing out and carrying out clogging deposits from the formation into the well cavity.

The problem is solved by applying the method of pulse hydraulic fracturing, which includes pumping fluid into the well cavity, generating periodic pressure pulses in the bottomhole zone in the form of a wave moving along the well cavity, which is formed with a periodic increase in pressure in the well, using valves, the first of which connects well cavity with a source of liquid under pressure, the second - with a drain tank, during hydraulic fracturing, the time of movement of the wave of movement of the mass of fluid 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 fractures the reservoir are closed, then the first valve is opened for the time during which the wave of movement of the fluid mass reaches the bottomhole zone and acts on the fractures of the reservoir, the duration of the time intervals between the periods of pressure increase and decrease, as well as the rate of decrease is estimated yes phenomenon, then the first valve is closed and the second valve is opened to reduce the pressure in the well to the initial value, the second valve is opened after a period of time and at a speed that ensures the removal of bridging agents, a hydropneumatic accumulator is connected to the line connecting the first valve and the source of fluid under pressure, the volume of which is determined by the flow rate of the well fluid when it flows into the reservoir, to form a pressure pulse in the bottomhole zone, the first valve is closed when the speed of movement into the well decreases after the first valve is opened, to form fluid flows in the bottomhole zone, the first valve is closed at the highest speed of fluid movement into the well after opening the first valve.

This method allows you to influence the reservoir mass either with pressure pulses to maximize the loosening of cracks between reservoir sections, spalling of reservoir fragments, development of a network of fractures, or by forming alternating multidirectional fluid flows that contribute to the erosion of clogging deposits and their removal into the well cavity, then drain the well fluid from the well to reduce the pressure of the well fluid to the original and remove the viscous fractions that float up to the wellhead.

A hydropneumatic accumulator is a metal cylindrical body filled with gas (usually nitrogen placed in an elastic balloon). When a liquid is pumped into the hydropneumatic accumulator, the gas is compressed, due to which the hydropneumatic accumulator can serve as an energy storage device.

The method is implemented as follows. At the wellhead, valves are installed, the first of which connects the well cavity with a source of liquid under pressure, for example, with a TsA-320 pumping unit, the second with a drain tank. The fluid is pumped into the well to the initial pressure level at which the formation fractures are closed.

The hydropneumatic accumulator is connected to a line connecting a source of liquid under pressure and the first valve. Since the hydraulic accumulator is connected to a source of liquid under pressure, liquid is pumped into it, and the gas inside is compressed.

At the moment the first valve is opened, the pressurized fluid begins to flow into the well. A high-pressure area is formed at the wellhead, which moves to the bottomhole zone and sets the well fluid in motion. Through the first valve, fluid enters the well cavity not only from a source of fluid under pressure, but also from a hydropneumatic accumulator, which contributes to a rapid increase in pressure and the formation of a steep front of a wave of fluid movement.

Under the influence of pressure applied to the wellhead, the velocity of the well fluid mass increases. Upon reaching the well sump, the wave of fluid movement rests against an obstacle and slows down sharply, which is accompanied by an increase in pressure. The pressure impulse in the bottomhole zone is formed from hydrostatic pressure, pressure at the wellhead and water hammer pressure. The inertia of the movement of the mass of the well fluid contributes to an increase in the duration of the pressure pulse.

An increase in pressure in the near-wellbore zone leads to the expansion of existing and the formation of new fractures, and a periodic increase in pressure leads to loosening and spalling of low-permeability fragments of the formation skeleton, the development of a network of fractures.

For optimal development of reservoir fractures, the first valve is closed after the impact of the pressure pulse on the reservoir rock, when the velocity of fluid movement into the well decreases. If it is necessary to wash out the bridging agents in the formation, the first valve is closed when the maximum speed of the well fluid movement towards the bottom is reached. When the first valve is quickly closed, the well fluid moves to the bottomhole by inertia, a rarefaction is formed in the wellhead zone, after moving to the bottomhole zone, the liquid column slows down, then changes direction to the wellhead, which is facilitated by the rarefaction in the wellhead zone. After moving the fluid to the wellhead and increasing the pressure in it, the movement slows down and changes direction to the bottom, etc.

The regular counter-parallel movement of the fluid mass in the bottomhole zone contributes to its flushing, separation of adsorption deposits from the walls of pore channels and cracks,

After damping of fluctuations of the borehole fluid, the second valve is opened, the borehole fluid is poured into the drain container, into which floating fragments of viscous bridging agents are simultaneously carried out. When the initial pressure is reached, the formation fractures close, the second valve is closed.

Wells with low bottomhole permeability are more profitable to treat with pressure pulses to create a network of fractures. It is more expedient to treat wells with relatively high permeability with alternating multidirectional fluid flows.

The amplitude and duration of the pressure pulse depends on the steepness of the high-pressure wave front, and therefore on the opening speed of the first valve. The amplitude and duration of the depression pulse depends on the steepness of the rarefaction wave front, and therefore on the closing speed of the first valve. The second valve also creates a differential pressure to create a surge of liquid outflow. Valves must be fast acting.

The time intervals between the moments of opening and closing of the valves are selected according to geological conditions in order to remove clogging deposits and create the maximum number of cracks. The operations of increasing and decreasing pressure in the bottomhole zone are repeated the required number of times.

The technology of pulse hydraulic fracturing and erosion of the bottomhole zone makes it possible to create fractures in the well that radiate from the wellbore. The main result is an increase in the effective radius of the well, involvement in the development of the entire thickness of the reservoir, involvement of the maximum number of productive layers and remote areas. In pulse hydraulic fracturing, the fluid flow rate is low. The changing pressure of the hydraulic fracturing, alternating with the intensive movement of the fluid, contributes to the uniform "loosening" of the near-wellbore zone of the formation and the washing out of bridging agents.

The well fluid may contain chemicals for more efficient processing. The method can be applied in conjunction with other types of treatment of the bottomhole zone: acid, thermal, acoustic, etc.

Claims (1)

A method for implementing impulse hydraulic fracturing, which includes pumping fluid into the well cavity, generating periodic pressure pulses in the bottomhole zone in the form of a wave moving along the well cavity, which is formed with a periodic increase in pressure in the well, using valves, the first of which connects the well cavity with a source of fluid located under pressure, the second - with a drain tank, 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 closing of the formation fractures are preliminarily estimated, the initial pressure is set in the well cavity, at which the formation fractures are closed, then the first valve open for the time during which the wave of movement of the fluid mass reaches the bottomhole zone and affects the formation fractures, evaluate the duration of the time intervals between the periods of pressure increase and decrease, as well as the rate of pressure decrease, then close the first valve or open the second valve to reduce the pressure in the well to the initial value, the opening of the second valve is carried out after a period of time and at a speed that ensures the removal of bridging agents, a hydropneumatic accumulator is connected to the line connecting the first valve and the source of fluid under pressure, the volume of which is determined by the flow rate of the well liquid when it flows into the formation, characterized in that to generate a pressure pulse in the bottomhole zone, the first valve is closed when the speed of movement into the well decreases after the first valve is opened; opening the first valve.