RU2507390C1 - Method of pulse hydraulic fracturing implementation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes creation of pressure differential between wellbore area and well cavity by means of creation of pressure periodic pulses in wellbore area. Preliminary estimated is time of displacement of fluid mass movement wave from the mouth to specified site of horizontal well and length of extension and healing of formation cracks in horizontal well with two mouths. Filling valve of the first mouth is opened relative to the second mouth with time delay for provision of fluid mass movement waves from both mouths to specified site of wellbore area simultaneously. In horizontal well with one mouth formed are two consequent fluid mass movement waves, time delay between the first and the second waves is chosen based on provision of simultaneous supply of the first and the second fluid mass movement waves repulsed from sump to the specified site of horizontal well.

EFFECT: obtaining high-pressure pulses on any specified site of horizontal well with hydraulic impact effect.

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Description

The 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 bottom-hole zone with asphalt-resin-paraffin formations and solids.

There is a known method of completing a well and a device for its implementation (Voldaev N.A., patent No. 2271441, Cl. ЕВВ 43 / П7), which includes launching a selective cumulative perforator containing sections with a separate cumulative charge in each section, creating a cut in the rock with the formation in the formation of a fan of channels in a plane perpendicular to the axis of the well by sectional alignment of the cumulative charges with the plane of the cut and their successive firing. 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 (Shipulin A.V., patent No. 2266404, CL. EVB 43/25), 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 well, which is formed during periodic opening of the well cavity on the mouth with the use of 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 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 processing the borehole zone of the formation (Shipulin A.V., patent No. 2344281, Cl. ЕВВ 43/25), during which the opening and closing of the topping and spout valves at the wellhead create periodic fluctuations of the wellbore fluid, ensuring the buildup of its mass in the mode resonance.

However, for the implementation of hydraulic fracturing, it is necessary to use pumping units and wellhead equipment of high pressure, frequent switching of which is difficult to achieve.

A known method of hydrodynamic fracturing (Zeitlin S.D., Kashik A.S., Lukyanov E.E., patent No. 16525191, Cl. ЕВВ 43/26), during which a pipe string with a weighted lower part is lowered into the well, filled well with a fracture fluid and they begin to periodically raise and lower the pipe string to the length of one candle, while the pipe string is lowered with acceleration until the rarefaction wave reflected from the mouth returns to the hydraulic fracturing interval, after which the pipe string is decelerated until the pipe reflected from the mouth compression waves in the hydraulic fracturing interval.

However, for the implementation of the method, it is necessary to bring hoisting and lifting works and the use of a lifting device capable of changing the speed of a massive column of drill pipes within a few seconds.

A known method of pulsed hydraulic fracturing (Shipulin A.V., patent No. 2392425, CL. EVB 43/26), adopted as a prototype, the implementation of which evaluate the time of movement of a wave of mass of fluid from the mouth to a given section of the bottomhole zone and the duration of expansion and closure formation cracks, establish a pressure in the well cavity at which the formation cracks are closed, open the fluid filling valve for a time during which the wave of fluid mass movement reaches the bottom-hole zone and acts on the formation cracks, then topping closed fluid valve is opened and fluid drain valves for reducing the pressure in the well to the starting value.

However, the pressure drop from the generated hydraulic shock affects only the section of the well located in the immediate vicinity of the sump.

The objective of the invention is to obtain high pressure pulses on any given section of a horizontal well by bringing the mass of the well fluid into a state of motion with acceleration and its braking with the creation of the effect of water hammer.

The problem is solved in that, using a method of implementing a pulsed hydraulic fracturing in a horizontal well, 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 fluid mass wave moving along the well cavity, formed during periodic leakage of well fluid into the drain tank through the fluid drain valve, and pressure increase in the well cavity through the vent topping up the fluid connecting the cavity of the well with a source of fluid under pressure, a preliminary estimate of the time the wave of movement of the fluid mass moves from the wellhead to a given section of the horizontal well and the duration of expansion and closure of the formation cracks, setting the initial pressure in the well cavity at which the formation cracks are closed , opening the valve topping up the fluid for a time during which the wave of motion of the mass of fluid reaches a given section of the horizontal well and acts on the cracks Asta, then closing the fluid filling valve and opening the fluid drain valve to reduce the pressure in the well to the initial pressure, in a horizontal well with two mouths, open the fluid filling valves of the first well relative to the second well with a time delay to ensure the arrival of fluid mass waves from both mouths to a given section of the bottom-hole zone at the same time, in a horizontal well having one mouth, open the valve topping up the liquid, after the formation of a wave of mass movement The liquid closes it, then the valve for adding liquid is opened again and a second wave of motion of the mass of liquid is formed, the time delay between the formation of the first and second waves of motion of the mass of liquid is chosen from the condition of ensuring the simultaneous arrival of the first and second waves of motion of the mass of liquid reflected from the sump to a given section horizontal well.

This method allows for hydraulic fracturing by the formation of hydropercussion pressure increase in any part of a horizontal well.

An example of a device for implementing the proposed method in a horizontal well having two mouths is illustrated by the drawing of FIG. 1, an example of a device for implementing the proposed method in a horizontal well having one well is illustrated by the drawing of FIG. 2, in which: 1 - a horizontal well; 2 - perforation of a horizontal well; 3 - the direction of motion of the wellbore fluid wave.

The method is implemented as follows. At the mouths of the well, valves are installed, the first of which connects the tubing cavity to the drain tank, the second - the annulus 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.

If the well has two mouths, then at the moment of opening the valve topping up one of the mouths, liquid from a source of liquid 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.

After a calculated period of time, the valve topping the second wellhead is opened, the fluid from the source of fluid under pressure begins to flow into the well, a high-pressure region forms, which moves to the bottomhole zone and drives the well fluid.

At a given section of a horizontal well, the waves of fluid motion collide, a hydraulic shock occurs. The pressure increase during hydraulic shock is calculated by the Zhukovsky formula:

ΔP _beats = ρ · Δv · c,

where ΔP _beats - increase in pressure in the bottom-hole zone;

ρ is the specific gravity of the liquid;

Δv is the change in the fluid velocity in the process of water hammer;

C is the shock wave propagation velocity.

When moving against the direction of the waves of the borehole fluid, the pressure of the hydraulic shock is proportional to the sum of the speeds of both flows. 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.

After a period of time sufficient to widen the formation cracks, close the topping valves of both mouths and open the drain valves, which is accompanied by a decrease in pressure in the well. When the initial pressure is reached, the formation cracks close, the drain valves are closed. The operation of increasing the pressure on a given section of a horizontal well 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 contribute 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.

If the well has one wellhead, then at the moment of opening the valve topping up, fluid from the fluid source under pressure starts flowing 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. After the formation of a wave of motion of the mass of fluid, the fluid filling valve is closed. The wave of motion of the mass of liquid reaches the sump, is reflected from it with increasing pressure due to the effect of water hammer in the sump and a partial loss of power.

After a calculated period of time after the formation of the first wave of motion of the mass of fluid, the valve for replenishing the fluid is reopened, the fluid from the fluid source under pressure begins to flow into the well, the second wave of motion of the mass of fluid is formed. The time delay between the formation of the first and second waves of motion of the mass of fluid is selected from the condition of ensuring the simultaneous arrival of the first and second waves of motion of the mass of fluid reflected from the sump to a given section of the horizontal well.

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.

Claims (1)

A method for implementing pulsed hydraulic fracturing in a horizontal well, 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 fluid mass moving through the cavity of the well that is generated by periodic leakage of the well fluid into a drain tank through a fluid drain valve, and pressure increase in the well cavity through a fluid topping valve connecting well bore with a source of fluid under pressure, a preliminary estimate of the time of movement of a wave of motion of a mass of fluid from the wellhead to a given section of the bottom hole zone and the duration of expansion and closure of the formation cracks, installation of the initial pressure in the well cavity at which the formation cracks are closed, opening the valve to top up the fluid for the time during which the wave of motion of the mass of fluid reaches a given section of the horizontal well and acts on the fractures of the reservoir, then closing the valve topping up the fluid bones and opening the fluid drain valve to reduce the pressure in the well to the initial value, characterized in that in a horizontal well having two mouths, the valves of the first mouth fluid are opened to open the second mouth relative to the second mouth with a time delay to ensure the arrival of waves of fluid mass movement from both the mouth to a given section of the horizontal well at the same time or in the presence of one wellhead open the valve topping up the liquid, after the formation of the wave of motion of the mass of liquid it is closed, then the fluid filling valve is opened again and a second wave of fluid mass movement is formed, the time delay between the formation of the first and second waves of fluid mass is selected from the condition of ensuring the simultaneous arrival of the first and second waves of fluid mass reflected from the sump to a given section of the horizontal well.

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