RU2277644C1 - Hydraulic drive of deep-well sucker-rod pump - Google Patents

Abstract

FIELD: oil producing industry.

SUBSTANCE: device is designed for recovery of oil from wells. Proposed hydraulic drive of deep-well sucker-rod pump contains hydraulic cylinder with piston and rod for connecting with sucker-rod string of deep-well pump. Pneumohydraulic accumulator is connected through separator to working liquid reservoir. Hydraulic distributor serves to deliver working liquid from reservoir by power pup into underpiston space of hydraulic cylinder or to return working liquid into reservoir. Piston reversing system includes upper and lower switches interacting with rod and electromagnetic hydraulic selector controlled by said switches and delivering working liquid to change over hydraulic distributor and separator. Hydraulic drive is furnished with additional pump and additional hydraulic distributor operated by electromagnetic hydraulic selector for alternate delivery of liquid from additional pump into pneumohydraulic accumulator or return of liquid into reservoir. Additional pump is installed on one drive with power pump. Excess pressure relief system is furnished with safety valves. Hydraulic distributor of power pump, electromagnetic hydraulic selector and safety valve are made with neutral position of working members of spools to provide starting mode of operation of power pump.

EFFECT: improved reliability of drive, simplified load compensation system, prevention of leaks of working liquid, increased efficiency of system.

Description

The invention relates to pumping equipment used for oil production from boreholes.

A known hydraulic deep well pumping installation, the hydraulic actuator of which contains coaxially and vertically mounted, rigidly interconnected hydraulic actuators and pneumatic balancing cylinders with pistons and a cavity connected to the pneumatic balancing cylinder and communicating with a source of compressed air. The hydraulic cylinder through the distributor is connected to the power pump and the discharge line. The annular cavity of the sealing of the hollow piston of the pneumatic balancing cylinder is connected to the pneumatic accumulator and is in communication with the pressure oil pipe [1. USSR author's certificate No. 1367620, MKI ⁷ F 04 B 47/02, 1987].

The main disadvantages of the known hydraulic drive are its complex design, due to the coaxial arrangement of the pistons and reducing its reliability, cumbersome compensation system with a source of compressed air, and significant leakage of the working fluid through the seals between the cylinders.

Closest to the claimed technical solution is a hydraulic actuator of a deep rod pump, comprising a hydraulic actuator cylinder with a piston and a rod for connecting to a column of rods of a deep pump, a reservoir for a working fluid, a pneumatic accumulator, a power pump, pipelines, a distributor for alternately supplying a working fluid from the reservoir to the power pump the over-piston and under-piston cavities of the hydraulic drive cylinder and for returning the working fluid to the tank, a reversing system for changing the direction of travel along piston, multiplier, in which the low-pressure cavity through the distributor is connected to the sub-piston cavity of the hydraulic actuator cylinder for communication with it during the piston stroke down, and the high-pressure cavity through the check valve is connected to the pneumatic accumulator and, through the second non-return valve and distributor, to the over-piston cavity of the hydraulic actuator cylinder for communication with it during the upward stroke of the piston, and flow cut-offs, one of which is installed in the pipeline communicating the piston cavity of the cylinder with a pneumatic accumulator And the second - in the pipeline, imparting the high pressure chamber of the multiplier with the drain line [2. RF patent No. 2241854, MKI ⁷ F 04 B 47/04, 2004].

A disadvantage of the known hydraulic actuator is that it is not balanced. There is no load balance during upstroke and downstroke. In this regard, a high-power pump is used in the hydraulic drive. The possibility of leakage of the working fluid is not ruled out.

The technical challenge facing the invention is to increase the reliability of the drive, simplify the load compensation system, eliminate leakage of the working fluid and increase the efficiency of the downhole pumping equipment.

To solve the technical problem, a hydraulic actuator of a deep-well rod pump containing a hydraulic cylinder with a piston and a rod for connecting to a column of rods of a deep-well pump, a reservoir for the working fluid connected to the reservoir through a pneumatic accumulator shutoff, a power pump with a hydraulic distributor for supplying the operating fluid from the reservoir to the piston by a power pump the cavity of the hydraulic cylinder or the return of the working fluid to the tank, pipelines and the reversing system to change the direction of the piston stroke of the hydraulic cylinder, including the upper and lower switches interacting with the rod and the electromagnetic hydraulic switch controlled by them, which supplies the working fluid for switching the control valve and the shut-off valve, is additionally equipped with an additional pump installed on the same drive as the power pump and with an additional hydraulic control valve controlled from the electromagnetic hydraulic switch for alternating liquid supply from the additional pump into the pneumatic accumulator or return to the tank.

The hydraulic drive of the deep-well sucker-rod pump is equipped with an overpressure relief system, including safety valves installed in the pipelines, which connect the working fluid supply line from the power pump to the control valve and the working fluid supply pipe from the additional pump to the additional control valve.

To ensure the starting mode of operation of the power pump, the hydraulic distributor of the power pump, the electromagnetic hydraulic switch and the safety valve installed in the pipeline communicating with the return line of the working fluid, the pipeline for supplying the working fluid from the power pump to the hydraulic distributor, is made with the neutral position of the working bodies when the flow of the working fluid through the control valve and the electromagnetic hydraulic switch is closed, and through the safety valve n free.

The drawing shows a diagram of the described hydraulic drive.

The hydraulic drive of the deep-well sucker-rod pump consists of a hydraulic cylinder 1 with a piston 2 and a rod 3, a reservoir 4 for a working fluid, a pneumatic accumulator 5, a main power pump 6 and an additional pump 7 of lower productivity. The pump shafts are driven by a common drive motor 8. The tank 4 is equipped with a filler neck, an air filter and level and temperature sensors to monitor the operation of the system.

The power pump 6 is connected by pipelines through the valve 9 to the tank 4, and the additional pump 7 through the additional valve 10 is connected to the pneumatic accumulator 5, which, in turn, through the additional valve 10, the flow regulator 11 and the cutter 12 of the working fluid flow is connected to the tank 4.

The reversing system (reversal) of the piston stroke and the rod of the hydraulic actuator cylinder includes inductive proximity switches 13 (upper) and 14 (lower), the signals from which are fed to the electromagnetic hydraulic switch 15, which supplies the working fluid (coming to it from the pumps 6 or 7 through check valves 16 or 17) for switching the control valves 9 and 10 and the compartment 12. The throttle system 18 is included in the reversal system.

To relieve excess pressure in the pipeline 19, which communicates the line 20 returning the working fluid with the pipeline 21, which serves to supply the working fluid from the power pump 6 to the valve 9, a safety valve 22 is installed, and in the pipe 23, which communicates the line 20 of the return of the working fluid with the pipe 24 , which serves to supply the working fluid from the additional pump 7 to the additional control valve 10, a safety valve 25 is installed.

The hydrodistributor 9 (power pump 6) and the electromagnetic hydraulic switch 15, as well as the safety valve 22 are structurally made with a neutral position of the working bodies (spools), in which the flow of the working fluid through the valve 9 and the switch 15 is blocked (they act as cutoffs), and through safety valve 22 is free.

Cranes 26, 27 and 37 ensure the safety of the working fluid when replacing elements of the hydraulic system, and taps 28 and 29 provide pressure relief from the pneumatic accumulator 5.

To maintain the temperature within acceptable limits, an air heat exchanger 30 and an electric heater 31 located in the tank 4 are used.

The cleaning of the working fluid supplied by the pumps 6 and 7 is carried out by pressure filters 32 and 33.

Pressure sensors 34 and 35 are designed to configure and adjust system parameters, as well as to monitor the operation of the system.

In the initial state (drawing), the piston 2 of the hydraulic cylinder 1 is in the lower position (the sensors 14 of the lower position are turned on, and the sensors 13 of the upper position are turned off). All electromagnets are turned off (the operating elements of the hydraulic control valve 9 and the electromagnetic hydraulic switch 15 are in the neutral position when the switch 15 and the hydraulic control valve 9 are closed and the valve 22 is free), the taps 26, 27 and 29 and the check valve 36 are open, and the shut-off valve 12 and the crane 28 are blocked.

When starting the electric motor 8, a signal is simultaneously supplied to the electromagnet 39 of the safety valve 22. The discharge line of the pump 6 is connected through an open valve (which acts as a discharge valve), the heat exchanger 30 and valve 37 with a capacity 4. The discharge line of the pump 7 through the valve 10 is also connected to the capacity 4. Such a start-up is necessary for smooth switching on of the electric motor and warming up the working fluid.

When a signal is applied to the electromagnet 38 of the electromagnetic hydraulic switch 15, its spool takes the extreme right position, at the same time the electromagnet 39 of the unloading and safety valve 22 is turned on, which from that moment performs only the safety function. The working fluid from the power pump 6 through the filter 32 and the check valve 16 enters the control line to the electromagnetic hydraulic switch 15. The working bodies (spools) of the control valve 9 and the shut-off valve 12 are moved to the extreme left position. In this case, the working fluid from the pump 6 through the control valve 9, the shut-off valve 12, the flow regulator 11 and the control valve 10 enters the pneumatic accumulator 5 until the pressure in the accumulator reaches the pressure that provides the force required to lift the pump rod string. Then the working fluid through the valve 9 enters the rod end of the hydraulic cylinder 1 under the piston 2, which ensures the lifting of the string of pump rods (not shown) connected to the rod 3. As soon as the piston 2 of the hydraulic cylinder 1 reaches its highest position, position sensors 13 are turned on. the piston stroke of the hydraulic cylinder, which is preparatory.

The signal from the position sensors 13 gives the command to turn off the electromagnet 38 and turn on the electromagnet 40 of the electromagnetic hydraulic switch 15, whose spool is in the extreme left position. In this case, the working fluid in the control line moves the working bodies (spools) of the control valves 9 and 10 and the shut-off valve 12 to the extreme right positions. The rod cavity of the hydraulic cylinder 1 through the valve 9 and the pipe 41 is connected to the inlet of the pump 6, which at this stage of work performs the function of a hydraulic motor. The piston 2 of the hydraulic cylinder 1 under the weight of the column of pump rods moves downward, displacing the working fluid from the rod cavity of the hydraulic cylinder. The check valve 36 is closed by the pressure of the working fluid. The discharge of the working fluid from the hydraulic motor (pump 6) is carried out through the valve 9, the heat exchanger 30 and the valve 37 into the tank 4.

The shaft of the pump 7 is driven by a hydraulic motor (pump 6) and an electric motor 8. The working fluid from the pump 7 through the filter 33 and the hydraulic distributor 10 enters the pneumatic accumulator 5. The maximum pressure in the pneumatic accumulator is limited by the setting of the safety valve 25. The pressure in the control line is supported by the pumps 7.

As soon as the piston 2 of the hydraulic cylinder 1 reaches its lowest position, the position sensors 14 are turned on. The signal from the sensors gives the command to turn off the electromagnet 40 and turn on the electromagnet 38. The working element (spool) of the electromagnetic hydraulic switch 15 is in the extreme right position. In this case, the working fluid in the control line moves the spools of the hydrodistributors 9 and 10 and the shut-off valve 12 to the extreme left positions. The pressure line of the pump 7 through the filter 33, the valve 10, the heat exchanger 30 and the valve 37 is connected to the tank 4. The pump 7 is unloaded.

The movement of the piston 2 of the hydraulic cylinder 1 up is due to the total flow rate of the pump 6 (through the filter 32 and the control valve 9) and the pneumatic accumulator 5 (through the control valve 10, the flow regulator 11 and the shut-off valve 12). When this check valve 36 opens. The pressure in the control line is supported by the pump 6. As soon as the piston 2 of the hydraulic cylinder 1 reaches its extreme upper position, the position sensors 13 are turned on. The cycle repeats.

The hydraulic actuator uses the recovery of the energy of movement of the column of sucker rods down under the action of gravity into the energy of compressed gas in a pneumatic accumulator. The amount of recovery is regulated by a safety valve 25.

Claims (3)

1. The hydraulic actuator of the deep-well rod pump, comprising a hydraulic cylinder with a piston and a rod for connecting to the column of rods of the deep pump, a reservoir for the working fluid connected to the reservoir through a pneumatic accumulator shutoff, a power pump with a hydraulic distributor for supplying the operating fluid from the reservoir to the piston cavity of the hydraulic cylinder by a power pump or return of the working fluid to the tank, pipelines and a reversing system to change the direction of the piston stroke of the hydraulic cylinder, including the bottom and lower switches and the electromagnetic hydraulic switch controlled by them, which supplies the working fluid for switching the control valve and the shut-off device, characterized in that it is equipped with an additional pump mounted on the same drive as the power pump and controlled by an additional hydraulic control valve for alternating liquid supply from the additional pump into the pneumatic accumulator or return to the tank. 2. The hydraulic actuator of the deep-well sucker-rod pump according to claim 1, characterized in that it is equipped with an overpressure relief system including safety valves installed in the pipelines communicating with the working fluid return line the working fluid supply pipe from the power pump to the hydraulic distributor and the working fluid supply pipe from an additional pump to an additional control valve. 3. The hydraulic actuator of the deep sucker rod pump according to claim 2, characterized in that to ensure the starting mode of operation of the power pump, the hydraulic pump of the power pump, the electromagnetic hydraulic switch and the safety valve installed in the pipeline communicating with the return line of the working fluid the working fluid supply pipe from the power pump in the valve, made with the presence of a neutral position of the working bodies, when the flow of the working fluid through the valve and the electromagnetic hydra The power switch is closed, and through the safety valve it is free.