RU11846U1 - DEEP BAR PUMP - Google Patents

Abstract

A deep sucker rod pump comprising a stepped cylinder and plungers arranged one above the other and connected in series rigidly between each other by means of a rod, mounted on a string of pump rods, an annular and a working cavity, the upper plunger being made of a smaller diameter, a suction valve installed at the pump inlet, and a discharge a valve, characterized in that the upper and lower plungers are hollow, and the rod connecting the plungers rigidly with each other is made in the form of a solid rod, while its length is made longer than each of the plungers, the discharge valve is installed in the lower part of the upper plunger, and the lower plunger is equipped with a poppet valve installed in its upper part in the form of a conical seat and a locking element with a conical surface, while the locking element is rigidly connected to the lower end of the rod, the upper end which is rigidly connected to the upper plunger, and on the outer surface of both plungers polyamide nozzles are fixed with the possibility of opening.

Description

DEEP BAR PUMP

The utility model relates to the technique of oil production, in particular, to deep sucker-rod pumps and is intended to be used for pumping oil from wells with a large gas factor, and, of course, low production rates.

A well-known traditional borehole pump for pumping fluid from a well containing a cylinder with a suction clan, a zero plunger with a rod and a pressure valve placed in the cylinder (see P.N. Lovrzdiko. Underground well repair. M., Goskomizdat, 1961, p. 76-77, Fig. 55).

A disadvantage of the known pump is the low filling factor of the pump when pumping formation carbonated liquids, reducing its performance. This is because when the plunger moves upward, a gas-liquid mixture flows into the pump cylinder through the suction valve, while a gas cap is formed under the pump plunger from the gas released from the liquid.

When the nlunger moves down, the discharge valve is held closed by the hydrostatic pressure of the liquid column. The gas below the plunger is compressed, and the plunger passes a significant part of the working stroke with the discharge valve closed. As a result, when the plunger moves up, the useful stroke of the nlunger decreases, and the volume of liquid taken in decreases.

In subsequent strokes, due to the presence of a gas cap, there may come a moment when the plunger, during the down stroke, passes the entire working stroke with the discharge valve closed, and during the upward stroke, the pressure of the compressed gas under the plunger will not allow the suction

IPC F04B 47/02

valve, i.e. both valves remain closed. As a result, the pump stops flowing.

Known deep sucker rod pump for pumping liquids with significant gas content, containing a stepped cylinder and plungers placed one above the other and sequentially interconnected by means of a hollow rod, mounted on a column of pump rods and installed in the cylinder with the formation of an annular and upper and lower working cavities, with the upper the plunger is made of a smaller diameter. At the pump inlet, a suction valve is installed, the discharge valve of the pump is made in the lower part of the hollow stem (see, for example, ed. Certificate of the USSR No. 1 015 113, class F 04 B 47/02, 1981).

Well production (oil and gas) during plunger downward movement from the lower working chamber through the hollow rod and the open pressure valve passes into the upper working chamber. Gas released from the liquid in the form of a gas cap flows through the channels into the annular cavity, from where during the plunger upward gas is forced out through the check valve into the annulus, and oil is supplied from the upper working cavity to the pump pipe string.

A disadvantage of the known deep-well sucker-rod pump is the lack of efficiency when pumping highly carbonated lhdkost. This is because the energy of the gas released from the liquid in the pump cylinder is not used to lift the liquid along the tubing string, and also due to the limited volume of the annular cavity, the gas cap is not completely displaced during plunger downward movement, which will lead to subsequent pump operation to reduce the pump flow rate and reduce its performance.

in addition, the device is complex in design and, therefore, unreliable in operation due to the presence of a large number of valves, and also because of the need for a strict selection of the diameters of the upper and lower stages to ensure that the annular cavity is filled only with gas.

The purpose of the utility model is to increase the efficiency of the pump by using the energy of the gas released from the pumped liquid to lift the liquid along the LCP, while simultaneously hardening the device and increasing the reliability in operation.

This goal is achieved by the fact that in the known deep sucker rod pump containing a stepped cylinder and plungers arranged one above the other and connected in series rigidly between each other by means of a rod, mounted on a column of pump rods, an annular and a working cavity, the upper plunger being made of a smaller diameter, the suction valve, installed at the pump inlet and discharge valve, it is new that the upper and lower plungers are hollow, and the rod connecting the plungers rigidly with each other is made in in the form of a solid rod, while its length is greater than the length of each of the nlungers, the discharge valve is installed in the lower part of the upper plunger, and the lower plunger is equipped with a poppet valve installed in its upper part in the form of a conical seat and a locking element with a conical surface, while the locking element rigidly connected to the lower end of the rod, the upper end of which is rigidly connected to the upper plunger, and on the outer surface of both plungers polyamide nozzles are opened with the possibility of opening.

Due to the fact that the pump plungers are hollow, it became possible to use the lower plunger sub-plunger space to form a gas cap during the suction of the produced fluid from the well, and also use the plunger cavities to pass the fluid through the pump, and make the rod connecting the plungers in the form solid rod.

And the execution of the rod in the form of a solid rod allows the plungers to be connected rigidly, and the execution of the rod length is longer than the length of each of the plungers, it allowed to form an annular cavity between the rod, cylinder and ends of the plzzher of increased volume, which would serve as an additional intermediate chamber for the gas cap from underneath the lower plunger, and the volume of this chamber is guaranteed to provide a complete replacement of the volume of gas released from the liquid in the working cavity by the same volume of liquid, which eliminates There is a harmful effect of the gas cap on the operation of the pump and thereby increase the coefficient of filling the working cavity with liquid.

The execution of the rod of increased length allows using standard lengths of the cylinder to use short length plungers.

The implementation of hollow plungers with different volumes and different cross-sections ensures the creation of rarefaction in the annular cavity during operation of the pump rod string down and thereby provides the conditions for the complete mixing of the gas cap from under the lower plunger with liquid from the annular cavity. And the implementation of the upper nolunger with a smaller diameter than the lower plunger allows us to provide conditions for the discharge valve to operate when the plunger moves down and push the gas cap along with the liquid in the tubing, as well as reduce the load on the drive part of the pump.

Due to the fact that the discharge valve is installed in the lower part of the hollow upper plunger, the annular cavity is provided through the hollow upper plunger with tubing.

Due to the fact that the lower plunger of the pump is equipped with a poppet valve installed in its upper part, the locking element of which is rigidly connected to the lower end of the rod, and the upper end of the rod is rigidly fixed to the upper plunger, while in the specified valve the interaction of the locking element and the seat occurs on conical surfaces First, reliable operation of the valve is ensured both during the stroke of the pump rod string up and down, and secondly, reliable communication (separation) of the working cavity with the annular cavity is ensured.

Polyamide nozzles, mounted externally on the plungers and opening under pressure, provide resistance to movement of the plunger and reliable operation of the poppet valve, as well as protect the pump from mechanical damage from proppant used for hydraulic fracturing.

Thus, the design of the inventive pump allows for a two-stage transmission of the pumped out gas-emulsion emulsion through the pump, to take the fluid through the stroke of the plunger, making it possible to extract oil mainly in the most difficult conditions:

- in wells with low debgggg;

-in wells with highly foamed liquid up to continuous foam;

-in wells with a large gas content.

Since pumping goes through the stroke, it is possible to choose the dimensions of the plungers, the ratio of their diameters so that the fluid in the well has time to accumulate by the time the pump is sucked.

Thus, the proposed design of the pump made it possible to eliminate the harmful effect of the gas cap on the pump, transfer it to the auxiliary (annular) cavity, and then release it through the discharge valve and the upper hollow plunger into the tubing, using gas energy to lift the produced fluid through the column RZhT.

The drawing shows the proposed pump, General view.

The deep-well sucker rod pump comprises a stepped cylinder 2 of the pump located in the tubing string, hollow upper 3 and lower 4 plungers of different diameters, the diameter of the upper plunger 3 being smaller than the diameter of the lower plunger 4, suction 5 and discharge 6 and poppet 7 valves. Hollow plungers 3 and 4 are rigidly connected to each other by means of a common rod 8, made in the form of a solid rod, while the upper plunger 3 is rigidly fixed to the column of pump rods 9. An annular cavity 10 is formed between the rod 8 and the inner surface of the cylinder 2, which serves as an additional the suction chamber, and the working cavity 11 is formed under the lower hollow plunger 4. In the upper part of the plunger 4 there is a poppet valve 7 having a tapered seat

12 and a locking element 13, the conical surface of which interacts with the conical surface of the seat 12. The locking element

13 valve 7 is rigidly connected to the lower end of the rod 8, the upper end of which is rigidly connected with the upper plunger 3. The length of the rod 8 is made longer than the length of each of the plungers 3 and 4, and the plungers themselves are made shortened. The suction valve 5 is installed at the pump inlet and is made ball, and the discharge valve 6 is installed in the lower part of the upper plunger 3 and is also made ball. Outside on

plungers 3 and 4 are fixed noliamide nozzles 14 with the possibility of opening under pressure.

The pump operates as follows.

In the initial (extreme upper) position of the plunger 3, the discharge valve 6 is kept closed by the hydrostatic pressure of the liquid column in the tubing 1. The poppet valve 7 is closed by the weight of the plunger 4. The suction valve 5 is closed. Under the lower plunger 4 is a pumped oil emulsion with gas released from it in the form of a gas cap.

At the beginning of the stroke of the string of pump rods 9, and with it the hydraulically loaded upper plunger 3 and the rod 8 down, the lower plunger 4 remains stationary and hangs relative to the pump cylinder 2, since the polyamide nozzles 14 on the plungers 3 and 4 open under pressure and are firmly pressed to the walls of the cylinder 2. As a result, the plate 8, moving, moves the locking element 13 of the valve 7 from the seat 12, and the poppet valve 7 opens. Relative rarefaction occurs in the annular cavity 10 due to the difference in the volumes of the hollow plungers 3 and 4, and gas from under the lower plunger 4 is displaced through the valve 7 into the annular cavity 10, and the volume of the subplunger space of the plunger 4 freed from the gas cap is filled with liquid displaced by gas from the gas annular cavity 10. Therefore, under the lower plunger 4, the oil will be without a gas cap, and in the annular chamber 10 there will be remaining liquid and gas from the subplunger cavity in it. In this case, the fluid pressure in the FCT 1 continues to keep the discharge valve 6 closed. With the further movement of the upper plunger 3 down, the specified plunger is recessed in the annular cavity 10, as a result, gas is compressed in it, and a pressure is created in the annular cavity exceeding the hydrostatic pressure of the liquid column in the tubing 1. As a result, the pressure valve 6 opens.

and the gas cap together with the liquid from the annular cavity 10 through the hollow plunger 3 is discharged into the RZhT 1.

During the course of the string of pump rods 9 upward, the upper plunger 3 and the rod 8 also move upward, as a result of which the locking element 13 of the valve 7 sits in the seat 12, thereby separating the annular cavity 10 and the working cavity 11. The discharge valve 6 in the plunger 3 continues to remain open , since when the plunger 4 moves upward, the volume of the annular cavity IO changes (due to different volumes of the plungers 3 and 4), and the pressure at this moment in the specified cavity exceeds the hydrostatic pressure of the liquid column in the tubing 1. Under the lower plzger 4 and in the working cavity 1 1, a vacuum is created, the suction valve 5 opens, due to which the working cavity AND is filled with a gas-liquid emulsion for the full length of the working stroke of the plunger. The gas released from the pumped liquid is collected at the top until the next cycle, forming a gas cap in the sub-plunger cavity of the plunger 4 above the separated liquid in the working cavity 11. Next, the cycle repeats.

Thus, the gas cap does not accumulate in the pump, but is pushed through it when the plunger moves downward, doing useful work to raise the liquid. The implementation of the intake of fluid through the stroke of the plunger ensures the accumulation of fluid in the well by the next moment of suction of the pump, which is especially important in low-yield wells. Head sector of patent licensing work of PermPIPIneft // Tss / T.A. Yushkina

Claims (1)

A deep sucker rod pump comprising a stepped cylinder and plungers arranged one above the other and connected in series rigidly between each other by means of a rod, mounted on a string of pump rods, an annular and a working cavity, the upper plunger being made of a smaller diameter, a suction valve installed at the pump inlet, and a discharge a valve, characterized in that the upper and lower plungers are hollow, and the rod connecting the plungers rigidly with each other is made in the form of a solid rod, while its length is made longer than each of the plungers, the discharge valve is installed in the lower part of the upper plunger, and the lower plunger is equipped with a poppet valve installed in its upper part in the form of a conical seat and a locking element with a conical surface, while the locking element is rigidly connected to the lower end of the rod, the upper end which is rigidly connected to the upper plunger, and on the outer surface of both plungers polyamide nozzles are fixed with the possibility of opening.