RU166611U1 - Borehole PUMP PUMP - Google Patents

Abstract

A downhole sucker rod pump containing a cylinder, a hollow plunger with a tube at the lower end, connected to an adapter, and having a bore with an external thread on the upper end, into which a nut is made, made with a conical side wall and holes for its rotation, a fluid flow rotator made in in the form of a screw and with a pipe communicating the cavity of the tube with the outer surface of the plunger, and between the nut and the end face of the bore there are two identical plate rings with radial slots and cylindrical walls at the ends of of petals bent and forming a truncated cone, expanding towards the nut, moreover, the petals of one lamellar ring are located opposite the radial slots of the other lamellar ring, characterized in that radial holes are made at the lower end of the sub, and the extreme lower sections of the walls of the radial holes are in the plane passing on the free end of the nut.

Description

The utility model relates to the oil industry and is intended for oil production from wells.

A well-known sucker-rod pump (A.S. USSR No. 909298 for an invention, M. Cl. F04B 47/00, published 05.03.1982), comprising a cylinder, a hollow plunger with a tube at the lower end, a fluid flow rotator made in the form of a screw and with a pipe communicating the cavity of the tube with the outer surface of the plunger. The specified pump is not used for long, because when the plunger moves upward, mechanical impurities that wear out the plunger pair fall into the gap between the plunger and the cylinder.

Closest to the proposed technical solution is a borehole sucker rod pump (RU 157507 U1, 12/10/2015) containing a cylinder, a hollow plunger with a tube at the lower end, connected to a sub, and having a bore with an external thread on the upper end, to which a nut is made with a conical side wall and holes for its rotation, a fluid flow rotator made in the form of a screw and with a pipe communicating the cavity of the tube with the outer surface of the plunger, and two identical squares are located between the nut and the end face of the bore inchatyh ring with radial cuts and cylindrical walls at the ends of the lobes which are bent and form a truncated cone, expanding towards the nut, the pitch of the plate rings are disposed opposite the radial slots of another plate ring. During the operation of this device, mechanical impurities accumulate in the space between the cylinder and the sub above the nut. They when the plunger moves wear the working wall of the cylinder and thereby reduce the life of the borehole sucker rod pump.

The technical task of the utility model is to increase the life of the pump by reducing the wear of the working wall of the cylinder by mechanical impurities.

The stated technical problem is solved in that in a borehole sucker rod pump containing a cylinder, a hollow plunger with a tube at the lower end connected to an adapter and having a bore with an external thread at the upper end, into which a nut is made, made with a conical side wall and holes for it rotation, the fluid flow rotator, made in the form of a screw and with a nozzle communicating the cavity of the tube with the outer surface of the plunger, and two identical plate rings with radially located between the nut and the end face of the bore with slots and cylindrical walls at the ends of the petals, bent and forming a truncated cone, expanding towards the nut, and the petals of one plate ring are located opposite the radial slots of the other plate ring, new is that there are radial holes at the lower end of the sub, with the lowermost sections the walls of the radial holes are in a plane passing along the free end of the nut.

In FIG. 1 is a schematic longitudinal sectional view of a sucker rod pump; in FIG. 2 is a view A of FIG. one; in FIG. 3 is a plan view of a ring.

The downhole sucker rod pump includes a cylinder 1 (Fig. 1), a suction 2 and a discharge 3 valve, a hollow plunger 4 with a tube (not shown in Fig.) At the lower end connected to a sub 5. On the upper end of the plunger 4 there is a bore 6 with an external thread 7. A nut 8 is turned onto this thread, made with a conical side wall 9 and holes 10 for turning it. A fluid flow rotator (not shown in FIG.), Made in the form of a screw and with a pipe communicating the cavity of the tube with the outer surface of the plunger 4. Between the nut 8 and the end face of the bore 6 are two identical plate rings 11 with radial slots and cylindrical walls 12 at the ends petals 13. The petals 13 are bent and form a truncated cone, expanding towards the side of the nut 8. The petals of one lamellar ring 11 are located opposite the radial slots of the other lamellar ring. At the lower end of the sub 5, radial holes 14 are made. Through these holes, when the plunger moves, mechanical impurities enter the space above the discharge valve. The lowermost sections 15 of the walls of the radial holes 14 are in the plane passing along the free end 16 of the nut 8, so that mechanical impurities do not accumulate above the nut 8 and do not wear out the friction wall of the cylinder 1 when the plunger moves.

The downhole sucker rod pump operates as follows. When the plunger 4 moves along the cavity of the cylinder 1 upward, the discharge valve 3 is closed, since under the action of the liquid column its ball is pressed to its seat. The plunger 4 moves the oil through the cavity of the cylinder 1 up. In this case, the cylindrical walls 12 of the petals 13 of the plate rings 11 prevent the penetration of mechanical impurities into the gap between the plunger and the cylinder, since the petals of one plate ring are located opposite the radial slots of the other plate ring. Mechanical impurities, which under their own weight fall down relative to the plunger, pass through the radial holes 14 of the sub 5 and fall into the space above the discharge valve 3. After the plunger 4 reaches its highest position, it begins to move down. Discharge valve 3 opens and suction valve 2 closes. When the plunger 4 moves downward through the fluid flow rotator (not shown in Fig.), Clean oil without mechanical impurities gets into the gap between the plunger 4 and the cylinder 1 from below. After plunger 4 reaches its lowest position, it begins to move up. Further, the operation of the deep-well sucker rod pump occurs similarly to the above. In the proposed borehole sucker rod pump, when the plunger moves upward, mechanical impurities enter the space above the discharge valve through the radial holes of the sub. Mechanical impurities do not accumulate between the cylinder and the sub and therefore do not wear out the working wall of the cylinder when the plunger moves. This reduces wear on the working wall of the cylinder and thereby increases the service life of the proposed borehole sucker rod pump.

Claims (1)

A downhole sucker rod pump containing a cylinder, a hollow plunger with a tube at the lower end, connected to an adapter, and having a bore with an external thread on the upper end, into which a nut is made, made with a conical side wall and holes for its rotation, a fluid flow rotator made in in the form of a screw and with a pipe communicating the cavity of the tube with the outer surface of the plunger, and between the nut and the end face of the bore there are two identical plate rings with radial slots and cylindrical walls at the ends of of petals bent and forming a truncated cone, expanding towards the nut, moreover, the petals of one lamellar ring are located opposite the radial slots of the other lamellar ring, characterized in that radial holes are made at the lower end of the sub, and the extreme lower sections of the walls of the radial holes are in the plane passing on the free end of the nut.

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