RU135735U1 - DRIVE BORE ROD DRIVE - Google Patents

Abstract

1. The drive of the downhole rod installation, comprising a working cylinder, divided by a piston into two cavities, and an auxiliary tandem cylinder with a rod with pistons fixed at its ends, installed to form four cavities - two piston cavities, the first of which is connected to a source of compressed gas, and the second is connected through the control valve to the discharge line with the pump and the drain line with the drain, and two rod, the first of which is connected through the control valve to the pump and the drain line to the drain line with the Yves, and the second - from the stem cavity of the working cylinder, characterized in that it is provided with two safety valves, one of which is installed in the discharge line of the first rod end of a tandem cylinder, and the second discharge line to the second piston chamber tsilindra.2 tandem. The downhole rod drive drive according to claim 1, characterized in that it is equipped with a rocker with a reactive lever interacting with a vertical guide, while the rod rotator has a standalone drive in the form of a hydraulic motor connected via a directional valve with a discharge line with a pump and a drain line with a drain.

Description

The utility model relates to hydraulic volume displacement machines, including hydraulic means, and can be used to actuate a borehole sucker rod pump designed to lift liquids from large depths of problem wedged wells.

Known hydraulic drives of lifting devices (US Pat. RU No. 2061913, IPC ⁶ F15B 1/02, publ. 1996; Pat. RU No. 2134360, IPC ⁶ F04B 47/04, publ. 1999; Pat. RU No. 2193111, IPC ⁶ F04B 47/04, publ. 2002), containing a working cylinder with a piston dividing it into two cavities, the rod of which is connected to the pump by a discharge line with a directional valve and with a drain - a drain line with a directional valve, and an air accumulator.

Closest to the claimed and adopted as a prototype is a hydraulic drive of a lifting device (US Pat. RU No. 2232295, IPC ⁶ F04B 47/04, publ. 2004), containing a working cylinder, divided by a piston into two cavities, and an auxiliary tandem cylinder with a rod with pistons fixed at its ends, installed with the formation of four cavities - two piston cavities, the first of which is connected to the pneumatic accumulator, and the second is connected through the directional control valve with a discharge line with a pump and a drain line with a drain, and two rods , The first of which is connected through the valve discharge line with the pump and the drain line with a drain, and the second - with the stem of the working cylinder cavity.

The disadvantages of such drives is the difficulty of their maintenance during the operation of problem wedged wells, due to the need for a complete disassembly of the downhole equipment - underground repair-wells to eliminate jamming of the pump rod string.

The objective of the proposed utility model is to simplify the maintenance of the drive during the operation of problem wedged wells, by providing the ability to eliminate jamming of the string of pump rods without disassembling the downhole equipment, as well as providing the ability to work in automatic mode with a problem well with constant fatal hang.

The problem is solved by improving the drive of a borehole rod installation containing a working cylinder, divided by a piston into two cavities, and an auxiliary tandem cylinder with a rod with pistons fixed at its ends, installed with the formation of four cavities - two piston, the first of which is connected to the pneumatic accumulator, and the second is connected through a hydraulic distributor with a discharge line with a pump and a drain line with a drain, and two rod ones, the first of which is connected through a hydraulic distributor a pump discharge line and drain line with a drain, and the second - with the stem of the working cylinder cavity.

This improvement lies in the fact that the actuator is equipped with two safety valves, the first of which is installed in the discharge line of the first rod cavity of the tandem cylinder, and the second in the discharge line of the second piston cavity of the tandem cylinder.

The installation of the first safety valve in the discharge line of the first rod cavity of the tandem cylinder allows to reduce the maximum force on the rod by supplying liquid to the drain and thus avoid failure of the hydraulic or downhole equipment in the event of jamming of the rod string when moving up.

The installation of a second safety valve in the discharge line of the second piston cavity of the tandem cylinder by supplying liquid to the drain eliminates the synchronization of the stroke of the working and tandem cylinder rods and the formation of vacuum in the rod cavity of the working cylinder in case of jamming of the rod string when moving down.

Setting the opening pressure of the second safety valve allows you to adjust the load at which the speed of the rod string begins to decrease, and setting the valve capacity adjusts the dependence of the decrease in speed on the load.

In addition, the drive can be equipped with a rotary lever with a reactive lever interacting with the vertical guide, while the rotary rotator has a standalone drive in the form of a hydraulic motor connected via a directional valve with a discharge line with a pump and a drain line with a drain.

The supply of the drive with the above-described booster makes it possible to ensure continuous rotation of the rod string, both when moving it down and up, and when stopping the reciprocating movement of the rod string.

The utility model is illustrated by the drawing, in which Fig. 1 shows a hydraulic diagram of the drive of a downhole pumping unit, in Fig. 2 - a rotary gear, in Fig. 3 - a top view in Fig. 2.

The drive of the downhole rod installation contains a working cylinder 1, divided by a piston 2 into two cavities 3 and 4, and an auxiliary tandem cylinder 5 with a rod 6 with pistons 7 and 8 fixed at its ends, installed with the formation of four cavities - two piston 9 and 10 and two rod 11 and 12. The first piston cavity 9 is connected to the pneumatic accumulator - capacity 13, and the second 10 - through the discharge / drain line 14 and valves 15 discharge line 16 with the pump 17 and the drain line 18 with drain 19. The first rod cavity 11 is connected through discharge / discharge line 20 and directional control valves 15 with discharge line 16 with pump 17 and discharge line 18 with discharge 19, and second 12 with rod end 4 of working cylinder 1. The actuator is equipped with two safety valves 21 and 22. Valve 21 is installed in discharge line 20 the first rod cavity 11 of the tandem cylinder 5, the second safety valve 22 is installed in the discharge line 14 of the second piston cavity 10 of the tandem cylinder 5. The actuator is equipped with a rotator 23 with a reaction arm 24, interacting with the vertical pressure leveling, made in the above embodiment in the form of a rack 25 of the frame. The rod rotator 23 has an autonomous drive in the form of a hydraulic motor 26 connected via a directional control valve 27 with a discharge line 28 with a pump 29 and a drain line 18 with a drain 19. To control the position of the directional valves 15 and 27, a control station 30 is connected to the sensors 31 and 32 of the extreme positions of the piston 2. Position 33 indicates the rod of the working cylinder 1, connected through the wellhead rod 34 with the column of rods 35.

The operation of the drive is as follows.

Before starting work in automatic mode, in manual mode, adjust valve 22 in accordance with the load on the rod when moving downward, and if it is necessary to reduce the maximum lifting capacity of the actuator when moving upward, adjust valve 21. Before starting work, piston 2 of working cylinder 1 is in the lower position, the rod of the tandem cylinder 5 is in the extreme right position in the drawing. The gas pressure in the container 13 and the associated piston cavity 9 is transmitted through the piston to the liquid in the cavity 12 and the liquid in the cavity 4 of the working cylinder 1, balancing the wellhead rod 34 and the associated rod column of the well pump. The valve spools 15 and 27 are in the upper position in the drawing, in which the first rod cavity 11 of the tandem cylinder 5 is connected to the pump 17. Under the action of the working fluid pressure generated by the pump 17 in the cavity 11 and the gas pressure in the pneumatic accumulator - tank 13 connected to the cavity 9 , the pistons of the tandem cylinder 5 move to the left according to the drawing, displacing the working fluid from the cavity 12 and creating a pressure in the rod cavity 4 of the working cylinder 1, under the action of which the piston 2 and the rod 33 connected to the mouth move evy rod 34, which is connected with the column of rods. The fluid from the cavity 10 of the tandem cylinder 5 is displaced through the directional control valves 15 to discharge 19. In case of jamming of the rod string when moving upwards and exceeding the load on the wellhead rod 34 above that, in order to prevent failure of the hydraulic or downhole equipment, a safety valve 21 is required, connected to the rod cavity 11 of the tandem cylinder 5 and in cases of exceeding the maximum pressure delivers the fluid pumped by the pump 17 to drain 19. When the piston 2 reaches its extreme upper position, yes a sensor 31, the signal from which is input to the control station 30. Depending on the set cycle time, the control station 30 switches the spools of the control valves 15 to the middle (providing a pause) and then to the lower position in the drawing at which the drive is reversed. The working fluid from the pump 17 enters the cavity 10 of the tandem cylinder 5 and, acting on its pistons, moves them to the right according to the drawing, the working fluid from the cavity 4 of the working cylinder 1 under pressure from the weight of the rod string transmitted through the wellhead rod 34 is displaced into the cavity 12 tandem cylinder 5, compressing the gas in the cavity 9 and the pneumatic accumulator 13, and from the cavity 11 of the tandem cylinder 5, the working fluid through the valves 15 is displaced to the drain 19.

The downward stroke, depending on the settings of the control station 30, lasts until the suspension of the sensor 32 reaches its lowest position, or until the end of the cycle time. If the suspension has reached the lower position sensor 32 before the cycle time has elapsed, then to ensure a predetermined number of swings, the suspension is stopped until the end of the cycle time. The control station 32 does not send a signal to the spools of the control valves 15 and 28 and the liquid from the pump 17 is fed to the drain 19. After the cycle time, the movement is repeated. In the case of jamming of the column of rods and associated wellhead rod 34 when moving downward, the pressure in the closed cavity formed by the rod cavity 4 of the working cylinder 1 and the rod cavity 12 of the tandem cylinder 5 decreases (the value tends to 0), while the pressure pumped by the pump 17 increases (the value tends to the gas pressure in the pneumatic accumulator 13). In order to avoid violation of the synchronization of the stroke of the working cylinder 1 and the tandem cylinder 5 and the formation of vacuum in a closed cavity, a safety valve 22 is required, which, when the pressure pumped by the pump 17 in the pressure piston cavity 10 increases to gas pressure, will begin to supply fluid to the discharge / drain line 20, connected through valves 15 to a drain 19. Thus, the setting of the opening pressure of the safety valve 21 regulates the load on the stem 33, at which the downward speed will begin to decrease, and u p valve capacity 21 regulates decrease dependence on the load speed. Thus, when the rod 33 hangs, the drive has the ability to operate in the following modes, depending on the settings of the control station:

Mode 1:

The upward movement is carried out in the usual way, and when moving downward, the rod 33 of the working cylinder 1 continues to move downward until the suspension of the sensor 32 reaches its lowest position, no matter how long the downward movement takes. If the suspension has reached the lower position sensor 32 earlier than the cycle time determined by the number of swings set by the control station 30, then the suspension is stopped until the end of the cycle time at the lower position sensor 32. In this case, the required stroke length is provided regardless of whether the number of swings is provided or not.

Mode 2:

The upward movement is carried out in the usual way, and when moving downward, the rod 33 of the working cylinder 1 continues to move downward until the suspension of the sensor 32 reaches the lower position or the end of the cycle time. If the cycle time has ended before the suspension has reached the lower position sensor 32, then the control station 30 gives a signal for upward movement. In this case, the required number of swings is provided, regardless of whether the stroke length is provided or not.

In the variant with the valve 23, the pump 29 through the valve 27 in one of its positions delivers the working fluid to the hydraulic motor 26 mounted on the wellhead rod 35 and drives it, and in the other position of the valve 27 the working fluid flows to the drain 19. The position of the valve 27 changes by signals from the control station 30. Thus, the rods 35 are rotated, while this process can occur both in a certain period of time, tuned by the control station 30, and constantly throughout Line speed and in moments of delays in the extreme positions.

Thus, the use of the proposed drive, due to the automatic operation, in which the speed and stroke length of the rod string changes proportionally to the load on the wellhead rod, and due to the possibility of continuous rotation of the rod string, ensures uninterrupted movement of the rod string, constant movement ( circulation) of the fluid and, as a result, washing the thick medium of the produced fluid and removing the paraffin deposits, and also provides the possibility of operating wells with a permanent unrecoverable head saniem.

Claims (2)

1. The drive of the downhole rod installation, comprising a working cylinder, divided by a piston into two cavities, and an auxiliary tandem cylinder with a rod with pistons fixed at its ends, installed to form four cavities - two piston cavities, the first of which is connected to a source of compressed gas, and the second is connected through the control valve to the discharge line with the pump and the drain line with the drain, and two rod, the first of which is connected through the control valve to the pump and the drain line to the drain line with the Yves, and the second - from the stem cavity of the working cylinder, characterized in that it is provided with two safety valves, one of which is installed in the discharge line of the first rod end of a tandem cylinder, and the second discharge line to the second piston chamber of the tandem cylinder. 2. The drive of the downhole rod installation according to claim 1, characterized in that it is equipped with a rocker with a reactive lever that interacts with a vertical guide, while the rod rotator has a standalone drive in the form of a hydraulic motor connected via a directional valve with a discharge line with a pump and a drain line with a drain.

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