RU2007618C1 - Well sucker-rod pump - Google Patents

Abstract

FIELD: oil and gas industry. SUBSTANCE: pump has a cylindric case provided with suction valve and fixed sealing unit and hollow plunger with a delivery plunger. The bottom of the case is provided with at least one additional sealing unit spaced from the main at a distance which follows a relationship available in the invention description. EFFECT: enhanced efficiency. 5 dwg

Description

 The invention relates to oil and gas engineering and can be used for pumping oil and other liquids from wells.

 Well-known sucker rod pumps of the plunger type, in which the plunger moves in a cylinder, the inner surface of which has high hardness and is also machined with high accuracy. The plungers of such pumps are either smooth metal with a gap seal between the cylinder and the plunger, or with a soft seal in the form of cuffs or split rings.

 The most significant drawback of such pumps is the need to manufacture a precision cylinder-plunger pair in which the cylinder length reaches 5 meters and above, and the plunger length is up to 2 meters, while the diameter of the cylinder and plunger ranges from 28 to 102 mm.

 Pumps are known in the art in which a smooth plunger is sealed by a fixed contact type sealing device whose relative length is small. In such pumps, the gap between the cylinder and the plunger is large enough so that during operation they do not touch each other. The stroke length of the plunger is relatively small. Typically, this type of pump is used in ground equipment.

 The use of pumps with a stationary seal of the plunger in oil wells with a vertical arrangement of the cylinder is impractical, since the increased clearance between the cylinder and the plunger with a long pump length significantly increases the dead space in the working chamber. The efficiency of such a pump will be low, especially in wells with a high gas factor.

 The aim of the invention is to increase the reliability of a borehole sucker rod pump with a plunger having a stationary seal.

 This goal is ensured by the fact that in the known borehole sucker rod pump comprising a cylindrical body with a suction valve and a stationary sealing device, as well as a hollow plunger with a pressure valve, one or more additional sealing devices are installed located in the lower part of the cylindrical body, and the distance between the sealing devices satisfies the following conditions: 2H + B> L ≥ H + B, where L is the length of the plunger, H is the distance between adjacent sealing devices, B is the length sealing device.

 The features of the proposed invention, both new (the presence of additional sealing devices located at a certain distance from each other), as well as known, form a combination previously unknown and not previously used, which allows us to consider the proposed seal in accordance with the criteria of the invention of "novelty."

 In addition, this set of features provides higher reliability of the downhole sucker rod pump in wells with a high gas factor, which allows us to recognize the claimed technical solution meets the criterion of "significant differences".

 In FIG. 1 is a diagram of a cylinder-free borehole sucker rod pump with two stationary plunger sealing devices; in FIG. 2-5 - the principle of operation of a cylinderless pump.

 The pump consists of a cylindrical housing 1 with an upper 2 and an additional lower 3 sealing devices for the plunger 4. At the bottom of the housing 1 there is a suction valve 5, and at the bottom of the hollow plunger 4 there is a pressure valve 6. The pump housing 1 in the upper part is connected to the pump the compressor pipes 7, and the plunger 4 - with a column of rods 8. The length of the plunger L should be greater than the distance between the seals N.

 The pump operates as follows.

 In FIG. 1 shows a plunger at bottom dead center (BDC). Both valves are closed and the fluid pressure in the working chamber 9 is equal to the fluid pressure in the tubing. The gas that entered the working chamber during the previous suction stroke is partially dissolved in the liquid and partially in the free state in the upper part of the working chamber 9.

 At the beginning of the upward stroke (see Fig. 2), the gas first expands in the chamber 9 until the pressure under the suction valve 5 exceeds the pressure in the working chamber 9. Then, the valve 5 opens and fluid flows from the well into the chamber. Due to the fact that the dead space of the chamber 9 is small compared to the total volume displaced by the plunger over the entire stroke length, the delay in opening the valve 5 will be insignificant.

 When moving upward (see Fig. 2), the upper part of the plunger 4 enters the upper sealing device 2, and its lower part simultaneously leaves the lower seal 3. At this moment, the chamber 10 overlaps from the pressure line 11 and the pump is filled with liquid from the annulus of space will continue with the suction valve open 5. In the chamber 10, during the suction stroke, a part of the liquid remains, the volume of which is equal to the volume of the annular space enclosed between the housing 1 and the plunger 4. There is also a solution in this liquid nny gas, the presence of which affect the pump filling.

 In FIG. 3 shows a plunger at top dead center (TDC). The cavities of the working chambers 9 and 10 are filled with liquid and partially gas. During the reverse stroke of the plunger 4 downward, gas compression and pressure increase in the working chambers first occur (see Fig. 4). When the pressure in the chambers 9 and 10 exceeds the pressure of the liquid column in the tubing, the pressure valve 6 will open and with a further movement of the plunger downward, the liquid will begin to flow into the pressure line of the pump. In this case, the compressed and dissolved gas will be collected in the annular space of the chamber 10 between the plunger 4 and the housing 1. When the plunger 4 passes the lower seal 3 and cuts off the chamber 10 from the chamber 9 and at the same time connects the tubing cavity 11 to the chamber 10, the gas freely leaves the chamber 10 into the tubing cavity and further to the pump discharge (see Fig. 5).

 This will prevent gas blocking of the pump, filling the working chambers will be complete and the pump will work with high volumetric efficiency despite the fact that the total dead space of such a pump is much larger than that of standard cylinder pumps with a smooth plunger or a soft seal plunger.

 Pump efficiency can be improved if mechanical seals (3,4) are used as sealing devices 2 and 3. (56) 1. Bezzubov A.V. et al. Pumps for oil production, a manual for a worker, M. Nedra, 1986, p. 187, fig. 81.

 2. USSR author's certificate N 1442699, cl. F 04 D 47/02, 1988.

Claims (1)

 A downhole PUMP PUMP, comprising a cylindrical body with a suction valve and a stationary sealing device, a hollow plunger with a pressure valve, characterized in that at least one additional sealing device is installed in the lower part of the cylindrical body, installed at a distance satisfying the condition: 2H + B> L ≥ H + B, where L is the length of the plunger; H is the distance between adjacent sealing devices; B is the length of the sealing device.

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