RU70321U1 - DEPTH DIFFERENTIAL ROD PUMP FOR SIMULTANEOUS-SEPARATE OPERATION OF TWO LAYERS - Google Patents

Abstract

The utility model relates to the oil and gas industry, in particular to pumps for the simultaneous separate operation of two oil reservoirs in a single column of elevator pipes. The purpose of this utility model is to create a pump for simultaneous separate operation of two layers extremely simplified and reliable, allowing sampling and pumping out of products of layers at different bottomhole pressures independently of each other, pumping it together to the surface along one column of elevator pipes driven by one column rods and consisting largely of parts and assemblies of the standard series. The proposed deep differential sucker rod pump consists of two pumps connected in series, namely: the upper and lower, having different diameters of cylinders and plungers and the design of the discharge and suction valves. The lower pump of smaller diameter, its cylinder and plunger are equipped with two valves: suction - the usual type used in pumps of the series, mounted concentrically at the pump inlet, and pressure - conical type and mechanically controlled. The upper pump has a conventional type discharge valve on the plunger, and a suction valve mounted on the side surface of the cylinder. A deep differential sucker-rod pump allows separate pumping of formation products regardless of their bottomhole pressures with a given capacity corresponding to the productivity of these layers using a single rod string and lift pipes. 2 illustrations.

Description

The utility model relates to the oil and gas industry, in particular to pumps for the simultaneous separate operation of two oil reservoirs in a single column of elevator pipes.

The well-known "Installation for the simultaneous separate operation of two layers" RF Patent No. 2221136 Cl Е21В 43/14, containing one pump and two suction valves, one of which is lateral.

The design drawback is the sensitivity of its suction valves to the different bottomhole pressures of the exploited formations and the associated danger of blocking one of the suction valves by the pressure of a high-pressure formation. This necessitates the primary pumping of oil from the low-pressure and then high-pressure reservoirs, which requires additional readjustment of the pump cylinders to position the side suction valve at a point dividing the cylinder in proportion to the reservoir productivity, and a liquid intake device for the primary pumping of products from the low-pressure reservoir.

Closest in principle to the proposed pump are design pumps with a double pump by R.A. Maksutov et al. (In the book "Simultaneous separate operation of multilayer oil fields." M. Nedra. 1974. p. 84) and differential pumps, designs authors V.A.Safin and others (in the books "Simultaneous separate exploitation of oil reservoirs. Tatar book publishing house. Kazan. 1967, and the" Reference book on oil production "edited by Dr. technical sciences Sh.K. Gimatudinova. M Bowels. 1974) and design ists NPU "Starogrozneft", described in detail in

the above-mentioned book by R.A. Maksutov, et al. (“Simultaneously Separate Operation of Multilayer Oil Fields”. M. Nedra. 1974. p. 85-86).

The design pump by R.A. Maksutov and others is not called differential by the authors, but is inherently such. It has a significant design flaw. When the pump plungers move upwards, according to the authors' opinion, the cylinders should be filled with formation products, but in fact due to the occurrence of vacuum in the chamber between the plungers under the influence of the pressure of the lower formation, the side suction valves of the upper pump, which are also small in size, will be blocked. Such situations are quite possible for several reasons, namely:

1. at different bottomhole pressures, when the lower layer will be more high-pressure;

2. in case of inaccurate determination of reservoir productivity or disproportionate selection of reservoir products due to a mismatch in the performance of one of the reservoir productivity pumps, which will cause a disproportionate and uncontrolled decrease or increase in reservoir and bottomhole pressure in one of the oil reservoirs;

3. when changing the reservoir and bottomhole pressure functionally associated with it in one of the layers due to the influence or absence thereof from the action of injection wells.

To prevent blocking of the upper suction valve, it is necessary to firmly hold the discharge valve of the lower pump in the seat with a force close, for example, to the pressure created by the liquid column in the lift pipes for the upper discharge valve. But this is a difficult task. For this reason, pumps of this type have not received recognition and have not been operated.

In the differential pump of Safin et al. Design, the lower pump mechanically connected by a hollow stem with a larger diameter plunger

the upper pump of the pipe type without valves, picks up and pumps the products of the lower reservoir. Thus, hydraulic isolation of the discharge valve of the plunger of the lower pump from the vacuum chamber between the pumps and hydraulic control of the closing of this valve by pressure in the lift pipes exceeding the bottomhole pressure of the lower layer are achieved. During the upward stroke of mechanically connected pump plungers, due to the difference in their diameters in the chamber between the pumps, a pressure vacuum occurs, which causes the suction valve to open on the side surface and to take off the production of the upper layer. During the downward stroke, the liquid is compressed in this chamber, which causes the side discharge valve to open and the suction valve to close reliably under the pressure of the annular liquid column. Oil pumping is carried out separately, production of the lower layer - along the tubing string, the upper - through the annulus.

The pump designed by the specialists of NPU Starogrozneft does not differ in principle from the above pump, but it is very difficult to manufacture and operate, in particular, due to the high gas factor of Grozny oils, which cause gas accumulation at the pump intake, and to solve the gas removal problem, the same from non-standard nodes.

The purpose of this utility model is to create a pump for simultaneous separate operation of two layers extremely simplified and reliable, allowing sampling and pumping out of products of layers at different bottomhole pressures independently of each other, pumping it together to the surface along one column of elevator pipes driven by one column rods and consisting largely of parts and assemblies of the standard series.

The proposed differential differential sucker rod pump consists of two pumps connected in series, namely: the upper and lower, having different diameters of cylinders and plungers and design

discharge and suction valves. The lower pump of smaller diameter, its cylinder and plunger are equipped with two valves: suction - the usual type used in pumps of the series, mounted concentrically at the pump inlet, and pressure - conical type and mechanically controlled. The upper pump has a conventional type discharge valve on the plunger, and a suction valve mounted on the side surface of the cylinder. A deep differential sucker-rod pump allows separate pumping of formation products regardless of their bottomhole pressures with a given capacity corresponding to the productivity of these layers using a single rod string and lift pipes.

Figure 1 and 2 shows the deep differential sucker rod pump in two positions (respectively, when the plungers move up and down). It consists of two pumps connected in series, namely: upper 2 and lower 7, having different diameters of cylinders and plungers, driven from a common column of rods 1.

The lower pump 7 of smaller diameter has a suction valve 12 and a conical discharge valve 11. The opening and closing control of the conical discharge valve 11 is mechanical due to the friction forces due to the pressure in the chamber between the lower pumps 7 and the upper 2. Therefore, the plunger 8 of the pump 7 is made integral. It has a movable part in the form of a hollow cylinder 10 with a conical hole for the conical discharge valve 11 in the lower part and a fixed middle part 9, to which the conical discharge valve 11 is mounted in the lower part, and the upper bracket (not numbered) for mounting the rod 6.

The upper pump 2 of a larger diameter is also equipped with two valves: discharge 4 on the plunger 3 and side suction 5, mounted on the side surface of the pipe connecting these pumps (not shown in the figure). The control of these valves 4 and 5 is hydraulic. Plungers 3 and 8 of pumps 2 and 7 are interconnected by means of a rod 6.

The cylinders of the pumps 2 and 7 are lowered into the well together with a column of elevator pipes (the column of elevator pipes is not indicated in the figure), which include a packer 14 located below the side suction valve 5 to separate the upper 15 and lower 16 oil reservoirs. After lowering the cylinders of the pumps 2 and 7 to a predetermined depth and reliable separation of the layers 15 and 16 in the production casing 13, the assembled plungers 3 and 8 on the rod string 1 are lowered by the packer 14.

The deep differential rod pump operates as follows.

During the course of mechanically connected plungers 3 and 8 of the pumps 2 and 7 upwards, a mechanically controlled closing of the conical discharge valve 11 occurs (diagram in figure 1). It happens like this. The hollow movable part of the plunger 10 remains stationary under the action of friction forces, and the moving conical discharge valve 11 of the pump 7 closes the conical hole of the hollow movable part of the plunger (the conical hole is not numbered in the drawing). Under the action of the pressure discharge occurring in the sub-plunger chamber of the pump cylinder 7, the suction valve 12 opens. The cylinder chamber of the lower pump 7 released due to the movement of the plunger 8 is filled with products from the lower layer 16. Simultaneously, when the mechanically connected plungers 3 and 8 move up due to the difference between the diameters of the cylinders of the upper 2 and lower 7 pumps in the chamber between the plungers 3 and 8 of the pumps 2 and 7 releases the volume ΔV equal to the difference between their areas ΔS = S ₁ -S ₂ and the stroke length of the plungers L, which causes a decrease in pressure there. The side suction valve 5, under the action of a differential pressure arising from the bottomhole pressure of the formation 15 and the discharge pressure in the pump chamber 2 and 7 between the moving plungers 3 and 8, opens, and products from the upper reservoir 15 enter the chamber between the pumps 2 and 7. Injection the valve 4 of the upper plunger 3 under the action of a liquid column in the elevator column is in a closed state, and products

wells, filling the plunger of the pump 2, when moving mechanically connected plungers 3 and 8 along the lift column is pushed to the surface.

After reaching the top dead center, the mechanically connected plungers 3 and 8 of the pumps 2 and 7 begin to move down (the diagram in figure 2). In the chamber between the cylinders of pumps 2 and 7, due to the movement of mechanically connected plungers 3 and 8 having different areas, there is a decrease in free space by a volume ΔV equal to the difference between their areas ΔS = S ₁ -S ₂ and the stroke length of the plungers L, which causes an increase pressure. The side suction valve 5 closes under this pressure, and the compressed borehole fluid from the chamber between the pumps 2 and 7 through the discharge valve 4 enters the supra-plunger part of the upper pump 2. At the same time, when the direction of movement changes due to friction, the hollow movable part of the plunger 10 is held in place, so the pressure cone valve 11 of the lower plunger 8 is torn off from the landing site, opening the passage. Products from the bottom of the pump 7 flows into its upper part, and then, together with the products that entered the chamber between pumps 2 and 7, flows into the upper overhead part of the pump 2. The suction valve 12 of the lower pump 7, to which the weight of the liquid column passes in the elevator the pipes closes. Next, the cycle repeats.

The theoretical capacity of the pumps will obviously be determined by the formula:

1. lower - Q = 1440 * S ₂ * L,

2. top - Q = 1440 * (S ₁ -S ₂ ) * L.

Thus, the proposed design of a deep differential sucker rod pump meets all the requirements specified above, that is, makes it possible to operate simultaneously and

separately of two layers with different bottomhole pressures, it is driven by one column of rods and allows you to pump the products of both layers to the surface along one column of elevator pipes. In comparison with other differential pumps, its design is extremely simplified, it is simple and reliable in operation, it is assembled from parts and assemblies of a typical size range of pumps. Another positive side of the proposed type of pump: it does not require additional costs for the changeover of pumps in accordance with the individual characteristics of the wells in terms of flow rate and reservoir pressure. The selection of the pump for the expected flow rates of the formations is carried out according to the usual rules, that is, according to the diameter and length of the stroke. If necessary, the pump unit can be disassembled and used for separate operation, that is, it is structurally made to a large extent using standardized units. The use of this type of pump allows to significantly expand the arsenal of technical means for simultaneous and separate operation of wells.

Claims (1)

A deep differential sucker-rod pump for simultaneous separate operation of two layers in a single column of elevator pipes, including two series-connected pumps driven by one rod string, characterized in that the upper pump has a larger diameter and is equipped with a side suction hydraulically controlled valve, and a plunger of the lower pump with a conical type pressure valve controlled mechanically, with the possibility of simultaneous and separate pumping of the products of both layers regardless of each other and their bottomhole pressures, and the joint pumping to the surface of one column of elevator pipes.