RU2601354C1 - Formation testing device - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to producing horizons in oil and gas wells testing devices. Device includes composite housing made of upper and lower parts interconnected by thread. In upper part in monolithic housing part standing type sampling chambers are made, which inlet channels are plugged with shut-off sleeves, interacting with cams. Monolithic housing part by means of thread is connected with bushing coaxially connected with branch pipe to make central axial channel to supply fluid into shut-off sleeves arrangement zone. Branch pipe lower end is made in form of socket with installed in it funnel made of elastic material, which diameter is larger than funnel diameter. Funnel edges are arranged below shutoff valve openings. Fluid intake control mechanism is installed with possibility of longitudinal movement relative to bushing. Locking sleeves, bushing, branch pipe and intake control mechanism are arranged in protective casing. Between casing and structural part there is gap for fluid flow into tube side. In device lower part hollow rod connected with fluid intake control mechanism, shutoff and equalizing valves are located.

EFFECT: technical result is device simplified design and smaller dimensions.

1 cl, 4 dwg

Description

The invention relates to devices for testing productive horizons in oil and gas wells.

A device for testing a formation is known, comprising a cylindrical body concentrically mounted in the body and a rod connected with a spline connection, rigidly connected to the sub for connecting to the pipe string, a thrust bearing installed between the body and the sub, an additional rod on the outer surface of which is made an endless helical groove, a bracket located in the helical groove, a spool sleeve with an inlet, telescopically connected to an additional rod and installed with the possibility of According to the invention, the device is equipped with a differential sleeve and a sealing cylinder covering the housing, the finger is placed directly in the housing with the possibility of coupling the outer surface of the finger with the inner surface of the sealing cylinder, the additional rod is mounted movably relative to the rod with a spline connection and the housing, the rod with spline connection in the middle part is provided with a shoulder with o-rings, below which are made radial holes section, the cross-sectional area of the collar of the sealing part is twice the cross-sectional area of the main part of the rod, and the differential sleeve is placed in the housing with the possibility of pairing its inner surface with the outer surface of the collar of the rod, while the collar is detachable (patent No. 2186967, publ. 08/10/2002).

A disadvantage of the known device is the inability to take sealed fluid samples from wells.

The closest to the invention according to the technical essence and the achieved result is a device for testing the formation, comprising a housing, shutoff and equalization valves, a hollow rod, on the outer surface of which an infinite helical groove is cut, a bracket installed in the stem groove, a shutoff valve sleeve connected to the bracket and sampling chambers, the inlet channels of which are blocked by locking sleeves, while the sampling chambers are placed on the outer surface of the stem between the locking and equalizing valves, and at the end of the shut-off valve sleeve a cam is installed with the possibility of interaction with the locking sleeves of the sampling chambers (av. St. USSR No. 670723, publ. 06/30/1979).

The known device allows the selection of sealed fluid samples from each formation separately and to ensure consistent filling of the chambers. However, the disadvantage of the known device is the complexity of its design due to the complex device of the sampling chambers, a large number of interacting parts and the difficulty in operation, because after lifting the samples to the surface, transferring them to a container for subsequent investigation requires almost complete disassembly of the device, as well as large dimensions in diameter, determined by the external arrangement of the chambers on the rod.

The task of the invention is to simplify the design and operation of the device, as well as reducing its size.

The problem is solved in that in the device for testing the formation, comprising a housing, shutoff and equalization valves, a hollow rod, on the outer surface of which an endless helical groove is cut, in which a bracket is installed, sampling chambers of a non-flow type, the inlet channels of which are blocked by shutoff sleeves, a mechanism control the fluid inlet into the sampling chambers with cams installed with the possibility of interaction with the locking sleeves, the housing is made of prefabricated, consisting of upper and lower parts, at In the upper part of the casing there are sampling chambers with inlet channels made in a monolithic casing part, and a fluid inlet control mechanism located under the shutoff sleeves, and a shut-off valve, a hollow stem connected to the fluid inlet control mechanism, and a balancing valve are located in the lower part ; the upper part of the body is equipped with a sleeve connected to a monolithic body part and with a pipe with the formation of a Central axial channel for supplying fluid to the location of the locking sleeves; the lower end of the pipe is made in the form of a socket with a funnel made of elastic material installed in it, the diameter of which is larger than the diameter of the socket, and the edges of the funnel are located below the holes of the shutoff valve; the fluid inlet control mechanism is mounted with the possibility of longitudinal movement relative to the sleeve; the sleeve and the nozzle for supplying fluid, the fluid inlet control mechanism and the shutoff sleeves are placed in a protective casing installed with a gap between it and the upper housing for the fluid to flow into the pipe space.

The execution of the housing assembly, consisting of upper and lower parts, and the placement in the upper part of the housing of the sampling chambers with inlet channels blocked by locking sleeves, and the fluid inlet control mechanism located under the locking sleeves, simplifies the operation of the device, since it is easier to disassemble on the surface - to ensure access to the inlet channels of the sampling chambers, only two operations are necessary - disconnecting the lower part of the housing and the casing. In addition, due to the placement of the sampling chambers in the upper part of the body, made in a monolithic body part, the dimensions of the device in diameter are reduced, and the design of the device is simplified by reducing the number of parts.

Installation of a sleeve in the upper part of the casing connected to a monolithic casing part and with a nozzle with the formation of a central axial channel for supplying fluid to the zone of location of the locking sleeves, and making the lower end of the nozzle in the form of a bell with a funnel made of elastic material with a diameter larger than the diameter the bell, and the edges of the funnel are located below the holes of the shutoff valve, as well as the placement of the sleeve, pipe, fluid inlet control mechanism and shutoff sleeves in the protective casing, which is installed with the sample By setting a gap between it and the upper part of the housing for fluid to flow into the tube space, it simplifies the operation of the device by supplying formation fluid to the sampling chambers regardless of the pressure of the incoming fluid - at low fluid pressure, the pressure of the tube space in the gap presses on the elastic funnel and ensures the flow fluid in the zone of location of the shut-off sleeves, and at high flow rates the edges of the elastic funnel bend and excess fluid flows directly into the tube space.

A general view of the formation testing apparatus is shown in FIG. 1-4.

The device for testing the formation contains a prefabricated housing made of interconnected threads of the upper part, consisting of body parts 1, 2, 3 (Fig. 1), and the lower part, consisting of body parts 4, 5 (Fig. 3), 6 (Fig. 4). In the upper monolithic housing part 1 (Fig. 1), sampling chambers 7 are of a non-flowing type, the inlet channels 8 of which are blocked by locking sleeves 9. The housing part 1 is connected by a thread to a sleeve 10, which is coaxially connected to the pipe 11 (Fig. 2) to form the Central axial channel 12 for supplying fluid to the location of the locking sleeves 9. The lower end of the pipe 11 is made in the form of a socket with a funnel 13 installed in it of elastic material, the diameter of which is larger than the diameter of the socket. The edges of the funnel 13 are located below the holes 14 of the shutoff valve.

On the sleeve 10, under the locking sleeves 9, a sleeve 15 (Fig. 2) of the fluid inlet control mechanism is installed, in which the cams 16 are located. The number of cams 16 must correspond to the number of locking sleeves 9 (Fig. 1) and, accordingly, the number of sampling chambers 7. Bushing the fluid inlet control mechanism 15 is mounted on the sleeve 10 by means of a housing 17 (Fig. 2), two split rings 18, 19 and a pin 20. In addition, longitudinal channels 21, 22 are made in the sleeve 15 of the fluid inlet control mechanism and the sleeve 10, and in case 17 - radial holes 23 for fluid duct.

The locking sleeves 9, the sleeve 10, the pipe 11 and the fluid inlet control mechanism 24, which is a group of parts 15, 16, 17, 18, 19, 20, are placed in the protective casing 25 (Fig. 2). Between the casing 25 and the casing part 2 there is a gap 26 for the fluid to flow into the tube space along the channel 27 made in the casing part 1 (Fig. 1).

In the lower part of the device there is a hollow rod 28 (Fig. 3), on the outer surface of which, for example, fifteen turns of right and left trapezoidal threads are cut. The ends of the threads are interconnected and form an endless helical groove, along which a bracket 29 slides, rigidly connected to the liner 30. The hollow stem 28 is connected to the fluid inlet control mechanism 24 through the parts system 31 (Fig. 3), 32, 33, 34, 35 (Fig. 2), 36.

Between the fluid inlet control mechanism 24 and the hollow stem 28 there is a shut-off valve, consisting of an adapter 37 and a sleeve 34 with holes 14 for fluid inlet from the well. The sleeves 38, 39 (Fig. 4) and the body part 6 have through holes and form a balancing valve controlled by the tension of the pipe string.

A device for testing the reservoir works as follows.

After the descent of the test tool with the device into the well to the desired formation, packing is performed. After creating the necessary load on the packer by rotating the drill string to the right for the required number of revolutions, for example 15, the hollow rod 28 (Fig. 3) moves to its lowest position and pulls the sleeve 34 along the telescopic connection of parts 31, 32, 33, resulting the shut-off valve opens by aligning the holes of the adapter 37 with the holes 14 of the sleeve 34. Since the edges of the elastic funnel 13 (Fig. 2) are located below the shut-off valve openings 14 and overlap them, after opening the shut-off valve, the borehole fluid is first and then after cleaning, the formation fluid begins to flow into the central axial channel 12, formed by the pipe 11 and the sleeve 10 (Fig. 1), into the zone of location of the locking sleeves 9 (shown by arrows) and flow around them. Then the fluid passes through the longitudinal channel 21 (Fig. 2) in the sleeve 15 of the fluid intake control mechanism and through the longitudinal channel 22 and radial holes 23 enters the area located under the housing 17, and then through the slots (not indicated in the drawing) in the part 35 enters through the gap 26 into the tube space along the channel 27 (Fig. 1). With a large flow rate of the well under the pressure of the flow, the edges of the elastic funnel 13 (Fig. 2) are bent and part of the flow passes through the gap 26 into the tube space 27.

When the borehole fluid in the cavity under the packers is completely replaced by formation fluid (determined by the technology) and the formation fluid begins to enter the pipe space through channel 27 into the location of the shutoff sleeves after the wellbore passes through the shutoff sleeves, the drill pipes rotate to the right using the same technology as described above. The rotational moment through the housing parts 4, 5 (Fig. 3), 6 (Fig. 4) is transmitted to the bracket 29 (Fig. 3) and the liner 30. The bracket 29, moving along an infinite helical groove, leads to the translational movement of the rod 28. The movement of the rod it is transmitted to the fluid inlet control mechanism 24 (Fig. 2) through parts 31 (Fig. 3), 32, 33, 34, 35 (Fig. 2), 36. In this case, the sleeve 34 moves upward and as a result of the opening 14 of the shutoff valve completely overlap . Full overlap occurs in the extreme upper position of the hollow stem 28, which is achieved by rotating the drill pipes by the number of revolutions corresponding to the position of the bracket 29 in the extreme lower turn of the trapezoidal threads on the hollow stem 28 (Fig. 3). The pin 20 (Fig. 2), moving along the curly grooves of the split rings 18, 19, makes the sleeve 15 and the cams 16 move. When the cams 16 coincide with the locking sleeves 9, they are triggered and the fluid enters the sampling chambers 7 through the inlet channels 8.

In the selective selection of sealed fluid samples from each formation separately, it is necessary to work with one cam 16. In this case, every four reciprocating movements of the rod 28 (every 15 turns to the right) lead to the opening of one of the shut-off valves 9 by the cam 16.

After the tests are completed, the tool is tensioned, as a result of which the sleeves 38 (Fig. 4) and 39 and the body part 6 additionally overlap the through holes for the fluid to pass from the well.

After lifting the tool to the surface, the upper part of the body, consisting of body parts 1, 2, 3, is unscrewed from the lower part, then the sampling chambers filled with a sealed sample are removed and sent for laboratory analysis.

The use of the claimed invention will simplify the design and operation of the device, as well as reduce its dimensions.

Claims (1)

A device for testing the formation, comprising a housing, shutoff and equalization valves, a hollow stem, on the outer surface of which an endless helical groove is cut, in which a bracket is mounted, sampling chambers of a non-flow type, inlet channels of which are blocked by shutoff sleeves, a mechanism for controlling fluid inlet into the sampling chambers with cams installed with the possibility of interaction with locking sleeves, characterized in that the housing is prefabricated, consisting of upper and lower parts, while in the upper part the housing has sampling chamber with inlet ports formed in the monolithic base member, and the inlet fluid control mechanism disposed under the locking sleeve and at the bottom - the shut-off valve, a hollow stem connected to the inlet of the fluid control mechanism, and the equalization valve; the upper part of the body is equipped with a sleeve connected to a monolithic body part and with a pipe with the formation of a Central axial channel for supplying fluid to the location of the locking sleeves; the lower end of the pipe is made in the form of a socket with a funnel made of elastic material installed in it, the diameter of which is larger than the diameter of the socket, and the edges of the funnel are located below the holes of the shutoff valve; the fluid inlet control mechanism is mounted with the possibility of longitudinal movement relative to the sleeve; the sleeve and the nozzle for supplying fluid, the fluid inlet control mechanism and the shutoff sleeves are placed in a protective casing installed with a gap between it and the upper housing for the fluid to flow into the pipe space.

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