RU2586693C1 - Pulse hydraulic fracturing method - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention can be used for development and recovery of production wells' yield, which decreased as a result of mudding of bottom-hole zone by asphalt-resin-paraffin formations and mechanical additives. Method includes pumping of liquid into the well cavity, formation of pressure drops between the bottom hole zone and the well cavity by creating periodic pressure pulses in the bottom hole zone in the shape of a travelling within the well cavity wave of liquid mass movement formed during periodic opening of the well cavity at the mouth for well fluid outflow, and increase of pressure by use of valves. During hydraulic fracturing, one previously estimates time of a liquid mass movement wave from the mouth to the bottom-hole zone and duration of expansion and closing of formation cracks. One sets in the well cavity an initial pressure at which formation cracks are closed. Then a liquid refilling valve is opened for the time during which the fluid mass movement wave reaches the bottom hole zone and acts on the formation cracks. Then one closes the liquid refilling valve and opens a liquid drain valve to reduce pressure in the well to the initial pressure value. To a line connecting the liquid refilling valve and a source of liquid under pressure, one connects a hydro-pressure-compensator, the volume of which is determined by formula V≥(3÷4)q, where q is the well fluid flow rate during its overflow to the formation under the pressure defined by the source of fluid under pressure.

EFFECT: obtaining in the well dibhole of pressure pulses with duration sufficient for deformation of cracks.

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Description

The present invention relates to mining and can be used to develop and restore the production rate of production wells, decreased as a result of mudding of the bottomhole zone with asphalt-resin-paraffin formations and solids.

A known method for the development and cleaning of the bottom-hole zone of wells by pulse drainage (patent No. 2159326, publ. 1999.12.15), in which the formation of a depression of the pressure difference between the bottom-hole zone of the formation and the cavity of the well is carried out by preliminary injection of fluid into the well, the creation of periodic pressure pulses in the bottom-hole zone formation in the form of a decaying standing wave moving along the well cavity and pressure release when fluid moves along the well from the bottomhole formation zone to the surface during sharp m borehole cavity opening.

However, the bottom-hole zone is poorly washed by well fluid since the water hammer has a short exposure time during which the formation cracks do not have time to fully open and close during the impact.

A known method of completing a well and a device for its implementation (patent No. 2271441, publ. 2006.03.10), comprising launching a selective cumulative perforator containing sections with a separate cumulative charge in each section, creating a cut in the rock with the formation of a channel fan in the formation in the plane perpendicular to the axis of the well, by sectionally combining the cumulative charges with the plane of the pit and sequentially firing them. Produce pulsed hydraulic fracturing.

However, for the implementation of pulsed hydraulic fracturing, it is necessary to use a cumulative perforator and additional perforation.

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

However, the bottom-hole zone is poorly washed by well fluid since the water hammer has a short exposure time during which the formation cracks do not have time to fully open and close during the impact.

The method of processing the bottom-hole zone of the well (patent No. 2344281, publ. 2007.05.14), including the formation of a depression of the pressure difference between the bottom-hole zone and the cavity of the well by creating periodic pressure pulses in the bottom-hole zone in the form of a wave moving along the cavity of the well, while the well mouth is previously connected with a receiver filled with gas, the fluid drain valve is opened when the borehole fluid moves from the bottom to the mouth with a frequency that ensures the buildup of its mass in resonance mode.

However, a receiver filled with gas is used to reciprocate the column of well fluid. The receiver is not designed for energy storage and shock wave formation.

A known method of processing the borehole zone of the formation (patent No. 2392425, publ. 2010.06.20), taken as a prototype, the implementation of which preliminarily estimates the time of movement of the wave of movement of the mass of fluid from the mouth to the bottom zone and the duration of expansion and closure of fractures of the formation, set in the cavity of the well the initial pressure at which the formation cracks are closed, then the valve topping up the fluid is opened for a time during which the wave of motion of the mass of fluid reaches the bottomhole zone and acts on the formation cracks, then discontinuity topping liquid valve and a fluid discharge valve is opened to reduce the pressure in the well to the starting value.

However, since the pump unit is most often used as the source of pressure, when the valve is opened, the pressure in the well drops sharply after a short high-pressure pulse. The wave of movement of the borehole fluid upon reaching the bottom does not have time to open and deform the formation cracks. For reliable crack opening, a pressure pulse with a duration of at least 0.5 seconds is required [1].

The objective of the invention is to obtain in the sump of the well high pressure pulses with a duration sufficient for the deformation of the cracks.

The problem is solved in that, using a method of implementing pulse fracturing, including pumping fluid into the cavity of the well, the formation of pressure drops between the bottomhole zone and the cavity of the well by creating periodic pressure pulses in the bottomhole zone in the form of a wave of fluid mass flowing along the cavity of the well that is produced during periodic opening a well cavity at the mouth for leakage of well fluid under pressure and increasing pressure using valves, one of the cats rykh - a fluid drain valve connects a well cavity to a drain tank, a second one - a fluid topping valve - with a source of pressurized fluid, opening and closing a well cavity at the wellhead for leakage of a pressurized fluid, carry out a fluid drain valve, increase the pressure in by connecting the wellhead with a source of liquid under pressure by opening the valve topping up the fluid, during hydraulic fracturing, the motion wave travel time is preliminarily estimated the fluid mass from the mouth to the bottomhole zone and the duration of expansion and closure of the formation cracks, set the initial pressure in the well cavity at which the formation cracks are closed, then the valve topping up the fluid is opened for a time during which the wave of movement of the fluid mass reaches the bottomhole zone and acts on formation cracks, then close the fluid filling valve and open the fluid drain valve to reduce the pressure in the well to the initial pressure, to the line connecting the fluid filling valve and the fluid source spine, pressurized gidropnevmokompensator connected, which volume is defined by the formula V≥ (3 ÷ 4) q, where q - rate of the well fluid at its overflow into the formation at a pressure determined by the liquid source under pressure.

This method allows, through the use of an energy storage device in the form of a hydropneumatic compensator, to form a pressure pulse with a duration sufficient to open the formation cracks.

The hydropneumatic accumulator is a metal cylindrical body filled with gas (usually nitrogen placed in an elastic balloon). When pumping liquid 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 to the drainage tank, the second, the well cavity with a source of fluid under pressure, for example, a fluid line designed for injection into injection wells or the CA-320 unit. The fluid is pumped into the well to the level of the initial pressure at which the formation cracks are closed.

The hydro-pneumatic accumulator is connected to the line connecting the source of liquid under pressure and the valve topping up the liquid. Since the hydropneumatic accumulator is connected to a source of liquid under pressure, liquid is pumped into it and the gas inside is compressed.

When the topping valve opens, fluid under pressure begins to flow into the well. At the mouth, a high-pressure region forms, which moves to the bottom-hole zone and drives the well fluid. Under the influence of pressure applied at the wellhead, the velocity of the mass of the well fluid increases. When the sump of the well is reached, the wave of fluid motion abuts the obstacle and sharply slows down, which is accompanied by an increase in pressure.

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

Through the topping valve, fluid enters the cavity of the well not only from a source of fluid under pressure, but also from a hydropneumatic accumulator. Suppose that a well fluid under pressure from a fluid source and a hydraulic accumulator is pumped into the formation at a flow rate (q) of 10 l / s. Therefore, in order to maintain high pressure for 3 sec, the hydro-pneumatic accumulator must have a volume of at least 3q, i.e. 30 liters. The volume of the hydropneumatic accumulator must have a reserve, since as the fluid expires, the pressure in the hydropneumatic accumulator decreases, which leads to a decrease in the pressure of the hydraulic shock at the bottom of the well.

After a period of time sufficient to expand the formation cracks, close the topping valve and open the fluid drain valve, which is accompanied by a decrease in pressure in the well. When the initial pressure is reached, the formation cracks close, the drain valve is closed. The operation of increasing the pressure in the bottomhole zone is repeated as many times as necessary.

The movement of the multi-ton mass of fluid affects both the bottom-hole zone and the formation array. Infralow frequencies have low attenuation, therefore, periodic changes in bottomhole pressure are transmitted in the form of low frequency waves along the strike of the formations and contributes to the redistribution of stresses in the array, which positively affects oil recovery.

Pulse hydraulic fracturing technology allows you to create several radially diverging cracks in the well. The main result is an increase in the effective radius of the well, involvement in the development of the entire thickness of the formation, inclusion of the maximum number of productive layers and remote areas. The mechanism of pulsed hydraulic fracturing is the propagation of waves along the fractures of the reservoir, the collision of pieces of the destroyed array. With pulsed hydraulic fracturing, the fluid flow is small. The changing hydraulic fracturing pressure contributes to uniform "loosening" of the borehole formation zone.

Well fluid may contain chemicals for more productive processing. The method can be applied in conjunction with other types of bottom-hole treatment: acidic, thermal, vibrational, acoustic, etc.

The source of information

1. Mikhalyuk A.V., Voitenko Yu.I. Impulse fracture of rocks. Academy of Sciences of Ukraine. Institute of Geophysics named after S.I. Subbotin. - Kiev: Science, Dumka, 1991 .-- 204 p.

Claims (1)

A method of implementing pulsed hydraulic fracturing, including pumping a fluid into a well cavity, forming pressure drops between the bottom hole zone and the well cavity by creating periodic pressure pulses in the bottom hole in the form of a wave of movement of a mass of fluid moving through the cavity of the well that is generated by periodically opening the well cavity at the wellhead for leakage well fluid under pressure and pressure increase using valves, one of which is a fluid drain valve the cavity of the well with a drainage tank is removed, the second is a fluid filling valve — with a source of pressurized fluid, opening and closing the well’s cavity at the wellhead for the flow of pressurized wellbore fluid is carried out by a fluid drain valve, increase the pressure in the well by connecting the wellhead with a source of liquid under pressure, by opening the valve topping up the liquid, during hydraulic fracturing, the time of movement of the wave of motion of the mass of liquid from the mouth to the bottomhole zone and the duration of 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 a time during which the wave of fluid mass movement reaches the bottomhole zone and acts on the formation cracks, then close the valve topping up the liquid and opening the valve for draining the liquid to reduce the pressure in the well to the initial value, characterized in that to the line connecting the valve topping up the liquid and the source of liquid, finding pressure, connect the hydropneumatic compensator, the volume of which is determined by the formula V≥ (3 ÷ 4) q, where q is the flow rate of the wellbore fluid when it flows into the reservoir under pressure, determined by the source of fluid under pressure.