RU2136849C1 - Well pulser - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: this relates to devices intended for intensification of well recovery of liquid materials such as fresh and mineral water. Well pulser has adapter with central passage for supply of liquid and side gas-supply passage with non-return valves installed in them. Connected to adapter are concentrically located relative to each other tubular body having shut-off valve in its lower part, and internal pipe functioning as gas-accumulator chamber. Space of gas-accumulator chamber is connected with side passage of adapter. Annular space is connected with central passage of adapter. Gas-accumulator chamber is provided with release valve installed in its lower part. Release valve of gas-accumulator chamber is made of material of specific weight less than of washing liquid. Release valve can be made in the form of turning shutter. Shut-off valve of well pulsator is made in the form of circular resilient member fitted over tapered rigid end-piece of diameter increasing upward and having limiting stops at top and bottom. Rigid end-piece is secured on end of pusher rod spring-biased relative to tubular body in device used for return of shut-off valve to initial position. It displaces relative to double-side seat secured on walls of tubular body above passages going into well. Lower part of release valve of gas-accumulator chamber and upper part of shut-off valve are provided with self-closing device. Application of aforesaid embodiment of well pulser allows for enhancing efficiency of pulsing action. EFFECT: higher efficiency. 4 cl, 10 dwg

Description

 A downhole impulse refers to the mining industry, in particular to devices for intensifying downhole extraction of liquid minerals, for example, fresh and mineral waters.

 A known projectile for downhole hydraulic production of friable and liquid minerals using an air-pulse device, including an agent-feeding pipe with a dispenser of discharged balls in the upper part, and with channel seats fixed on the inner surface of the walls of the lower part of the pipe [1].

 The disadvantages of the known projectile include the fact that to create pulses with high energy, gas and gas-liquid mixtures supplied to the well by expensive and scarce high-pressure boosters are used as agents, and balls transported through the channels of the agent supply pipes are used to block the channels of the valve seats, relatively small diameters. The latter circumstance necessitates the use of valve seats with small areas of channel cross sections, which causes a decrease in the energy of pulses of the ejected compressed air when forcing elastic balls through the valve seats.

 Known hard reflector of hydraulic waves, including a tubular body, an insert of two concentrically placed pipes, the upper and lower adapters for connection with drill pipes and with a hammer for intensifying well drilling. Insert pipes form a reflective cavity of two concentric chambers communicating with their upper parts, and at the bottom having a liquid inlet through the hole of the central pipe and a dead end formed by the walls of the external and internal pipes of the insert and the bottom [2].

 The concentric chambers of the reflector with atmospheric air, previously compressed by a column of well fluid during descent into the well and then compressed by flushing fluid during the operation of the hydraulic hammer valve, can act as a gas accumulator.

 However, the operation of such a gas battery is ineffective due to the small potential energy reserve of compressed to a thin layer of atmospheric air and significant losses of this energy when the liquid is ejected through small-sized channels and a complex section.

 The purpose of the invention is to increase the efficiency of the pulse effect on the water intake parts of the wells and deep zones of the reservoirs by increasing the energy capacity and reducing energy losses when pulses exit the gas accumulator to the well.

 This goal is achieved in that the downhole impulse includes an adapter with a central channel for supplying fluid and a side gas supply channel with check valves installed in them.

 A tubular body concentrically arranged relative to each other is connected to the adapter, a shut-off valve is installed in the lower part of the tube, and an inner pipe acting as a gas storage chamber. The cavity of the inner pipe is connected to the side channel, and the annular space between the tubular body and the inner pipe is connected to the central channel of the adapter.

 New in the design of the downhole impulse is that the gas storage chamber is equipped with an exhaust valve installed in its lower part. The exhaust valve of the gas storage chamber may be made of a material whose specific gravity is less than that of the washing liquid, or in the form of a rotary valve. A distinctive feature of the shutoff valve of the downhole impulse in front of existing structures is that it is made in the form of an annular elastic element, dressed on a conical rigid tip with a diameter increasing upward. Above and below, the conical rigid tip has restrictive stops and is mounted on the end of the device spring-loaded relative to the tubular body of the push rod to return the shutoff valve to its original position. The rod-pusher moves with a conical rigid tip relative to the double-sided saddle mounted on the walls of the tubular body above the radial channels.

 Additional differences in the design of the downhole impulse is that the exhaust valve of the gas accumulator chamber is made in the form of a rotary valve, and the lower part of the exhaust valve of the gas accumulator chamber and the upper part of the shut-off valve are equipped with an interlocking device.

 This embodiment of the downhole impulse provides the opportunity before filling the well with a balloon gas (air or nitrogen) to fill the gas accumulator or pump it with air using compressors with low productivity under pressure equal to or approaching the value of the pressure of the wellbore fluid column in the interval of processing the productive horizon. After the downhole impulse is lowered into the well and the rig pumps are turned on, the gas is compressed by the flushing liquid to a pressure of 4 MPa or more, which allows a high-pressure hydraulic shock to be obtained when the shut-off valve is opened and the portion of the flushing liquid is ejected into the well. In deep wells with a high column of well fluid, gas or GHS should be used as a working agent.

 In FIG. 1 shows the design of a downhole impulse installed in a water well; in FIG. 2 and FIG. 3 - cross-sections along I-I and II-II of the pulsator shown in Fig.1; in FIG. 4, FIG. 5 and FIG. 6 - node A of the shutoff valve of the pulsator with the image of a conical rigid tip and an annular elastic element, respectively, at the moments: in FIG. 4 - gas compression in the gas accumulator and forcing the flushing liquid down through the two-way saddle; in FIG. 5 - opening of radial channels in a tubular body for the exit of flushing fluid into the well at the time of water hammer; in FIG. 6 - advancement of the annular elastic element through the double-sided seat upward when the shut-off valve returns to its original position; in FIG. 7 is an embodiment of an exhaust valve of a gas storage chamber in the form of a rotary valve; in FIG. 8 is a sectional view of the outlet valve of FIG. 7 in the form of a rotary valve according to III-III.

 In FIG. 9 - the position of the working elements of the interlocking device at the time of capture and pressing of the exhaust valve to the saddle of the inner pipe; in FIG. 10 is a view in B of the key interlocking device.

 The downhole impulse (Fig. 1 - Fig. 10) includes an adapter 1 with a central channel 2 for pumping fluid and a side gas channel 3 with check valves installed in them. A tubular body 4 and an inner tube 5 are concentrically arranged relative to each other and connected to the adapter. The space 6 between the tubular body 4 and the inner tube 5 is connected to the central channel 2 of the adapter 1, and the inner tube 5, which acts as a gas accumulator, communicates with the side gas supply channel 3.

 In the lower part of the tubular body 4, a shut-off valve 7 is installed in the form of an annular elastic element 8, dressed on a conical rigid tip 9 with a diameter increasing upward. The rigid tip 9 has restriction stops 10 above and below and is fixed on a cone spring-loaded with a spring 11 relative to the bottom 12 of the tubular body 4 of the rod-pusher 13 of the reset device. The rod-pusher 13 together with the annular elastic element 8 is placed in the borehole pulsator with the possibility of movement relative to the double-sided saddle 14, mounted on the walls of the tubular body 4.

 The rod-pusher 13 in the middle part has a centralizer 15, and at the bottom is equipped with a support shoe 16.

 The tubular body 4 is made with radial channels 17 located under the bilateral saddle 14.

 The lower end of the inner pipe 5 is equipped with an exhaust valve 18, the set of which includes the actual valve 19 and the seat 20. The valve can be made in the form of a ball or cylinder with a lower conical part. The material from which valve 19 is made has a weight less than that of flushing fluid. The exhaust valve 18 can be made in the form of an elastic shell filled with liquid (Fig. 1) with a compression ratio close and specific gravity less than that of the washing liquid.

 The exhaust valve 18 of the gas storage chamber can also be made in the form of a rotary valve 21 with a sealing gasket 22, mounted on the axis 23 and pressed by a torsion spring 24 to the bottom 25 of the gas storage chamber (Fig. 7). One end of the torsion spring is fixed in the bottom, and the other on the axis of the rotary valve. In the rotary valve 21 and the bottom 25, sector windows 26 and jumpers 27 are made.

 The lower part of the exhaust valve of the gas accumulator chamber and the upper part of the conical rigid tip of the shut-off valve are equipped with an interlocking device 28. The interlocking device is made in the form of a keyhole 29 in the lower part of the exhaust valve 19 or axis 23 (Fig. 7) and a key 30 mounted on the upper part of the conical hard tip 9. For more reliable fixation of the rotary valve 21 relative to the bottom 25 of the gas storage chamber with closed sector windows, a pin lock is installed on the bottom of the camera p 31, and a rotary gate valve hole 32 is made.

 Downhole impulse operates as follows.

 Before lowering the pulsator into the well, the depth of the face and the location of the boundaries of the intake part, as well as the height of the column of the borehole fluid over the interval of pulse processing, are measured.

 Then calculate the value of the pressure of the borehole fluid at the depth of the pulse action in the well. Then, by connecting a can of compressed gas or using a compressor, gas is pumped through a non-return valve and a lateral gas supply channel 3 to a gas accumulator to a pressure equal to the pressure of the borehole fluid at the depth of the pulsed treatment of the borehole.

 To prevent gas leakage when pumping into the gas accumulator, you can use the interlocking device 28 and the rod-pusher 13, tightly pressing the exhaust valve 18 to its seat 20.

 After gas injection into the gas accumulator is completed, the downhole impulse is lowered by pipes to the lower interval of the water intake part of the well. Then, flushing fluid is pumped through the pipes through the non-return valve of the central channel 2 of the adapter 1, through the space 6 between the tubular body 4 and the inner pipe 5 into the cavity of the tubular body between the outlet 18 and the shut-off valve 7 by the mud pump.

 In this case, first, under the action of the flow of washing liquid, an annular elastic element 8 is fed down together with a conical rigid tip 9, which block the channel of the double-sided seat 14. Then, under the action of increasing pressure of the washing liquid, valve 19 will be squeezed from the seat 20 and the gas enclosed in the gas accumulator will be squeezed to design pressure at which the shut-off valve 7 will be forced through the two-way seat 14.

 Then, the elastic element, sliding along the inner walls of the tubular body 4, will open the radial channels 17 for pulsed ejection of the washing liquid under the action of a gas expanding in the gas storage chamber. This will cause compression of the spring 11 of the rod-pusher 13, abutting in the bottom 12 of the tubular body. The magnitude of the energy arising from this water hammer depends on the volume of the gas storage chamber, the pressure of the compressed gas, the cross-sectional area of the radial channels 17 in the tubular body 4.

 Since the exhaust valve is made of material lighter than the flushing fluid, and it floats on the surface of flushing fluid "O" entering the gas accumulator, the entire volume of fluid involved in gas compression when the shut-off valve is opened will be ejected through the radial channels of the tubular body into the well .

 After a pulsed ejection of flushing fluid and creating a water hammer in the well, the flushing fluid pressure above the shutoff valve 7 will drop, and the annular elastic element 8, dressed on a conical rigid tip, will be raised under the action of the spring 11 of the push rod 13 to contact with the lower side of the double-sided seat 14.

 Moreover, due to the displacement of the annular elastic element 8 downward and the formation between it and the rod-pusher 13 of an annular gap, the shut-off valve 7 will be forced upward without significant effort through the two-way seat 14 and returned to its original position.

 At a significant pressure of the liquid column in the pipes on which the impulse is lowered into the well, the shutoff valve 7 can also be returned to its original position by pushing it through the double-sided saddle with the rod-pusher 13 when the downhole impulse is lowered to the bottom of the well and the support shoe 16 rests against it.

 After the shut-off valve returns to its initial position, the pulsator rises to the next interval for processing the water intake part of the well and the pulse processing process is repeated.

 The difference in the operation of a downhole impulse with an exhaust valve in the form of a rotary valve from an exhaust valve made lighter than the flushing liquid consists in the operations for preparing the gas accumulator chamber and injecting gas and fixing the rotary valve from spontaneous opening.

 The overlapping of sector windows 26 of the bottom 25 of the gas storage chamber is carried out before pumping compressed air by pressing the rotary valve with a key 30 inserted into the keyhole 29 with simultaneous rotation. When the sector windows 26 of the bottom are completely blocked by 25 sector jumpers 27 of the rotary valve 21 and the lock pin 31 enters the hole 32, the key 30 is removed from the keyhole.

 The output of pin 31 from the hole 39 during the injection of air and the descent of the impulse into the well will be prevented by the pressing force of the torsion springs and the pressure of the compressed air to the valve 21. The opening of sector windows 26 of the bottom by sector jumpers 27 of the valve 21 in the pulse processing zone will be carried out by raising the valve to exit the pin the latch 31 from the hole 39 of the valve with increasing pressure above the shutoff valve 7 when forcing it down through the two-way seat 14.

 When unlocked, the valve 21 will be rotated to its original position under the action of the torsion spring 24.

 The most effective is the use of a downhole impulse when uncoating filters and processing the deep zones of water-bearing rocks in wells up to 100 m deep using drilling rigs equipped with mud pumps with a working pressure for pumping out flushing fluid of more than 4 MPa and equipped with compressors with a compressed air pressure of 6 MPa.

Sources of information
1. Patent of the Russian Federation N 2012812, MKI E 21 C 45/00, 1994

 2. USSR author's certificate N 823555, MKI E 21 B 4/00, 1981

Claims (5)

 1. A downhole impulse, including an adapter with a central channel for supplying fluid and a side gas supply channel with check valves installed in them, connected to the adapter and concentrically placed relative to each other, a tubular body, in the lower part of which a shut-off valve is installed, and an inner pipe that performs the role of the gas storage chamber, the cavity of which is connected to the side channel of the adapter, and the annular space - with its central channel, characterized in that the gas storage chamber the measure is equipped with an exhaust valve installed in its lower part.  2. The downhole impulse according to claim 1, characterized in that the exhaust valve of the gas accumulator chamber is made of a material whose specific gravity is less than that of the washing liquid.  3. The downhole impulse according to claim 1, characterized in that the exhaust valve of the gas storage chamber is made in the form of a rotary valve.  4. The downhole impulse according to claim 1, characterized in that the shut-off valve is made in the form of an annular elastic element, worn on a conical rigid tip with a diameter increasing upward and having restrictive stops above and below, mounted on the end of the rod-pusher device spring-loaded relative to the tubular body to return to its original position to moving relative to the two-sided saddle mounted on the walls of the tubular body above the radial channels.  5. The downhole impulse according to claim 1 or 4, characterized in that the lower part of the exhaust valve of the gas accumulator chamber and the upper part of the shut-off valve are provided with an interlocking device.

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