RU2125186C1 - Drive of well pumping unit - Google Patents

Abstract

FIELD: driving two deep well sucker-rod pumps. SUBSTANCE: air-loaded hydraulic accumulator 17 is made in form of tandem cylinder with rod 19 having pins 20 and 21 secured at its ends and two hydraulic chambers 22 and 23; each chamber is connected with rod ends of drive cylinders 1 and 2. pressure of working fluid in chambers 22 and 23 and in chambers 3 and (3′) may be equal (at equilibrium of both wells) and different (when equilibrium is disturbed) due to creation of pressure in chamber 28 of air-loaded hydraulic accumulator 17, thus making it possible to operate well pumps at balanced load, at disturbed balance and during operation of one pump. EFFECT: enhanced reliability. 1 dwg

Description

 The invention relates to hydraulic volume displacement machines designed to lift liquids from great depths, and can be used to actuate two sucker rod pumps installed in wells.

A well-known group hydraulic actuator of deep-well sucker-rod pumps containing hydraulic cylinders whose rod cavities are interconnected, and rodless cavities with a power pump through a controlled distributor (USSR author's certificate 800419 M. Cl ³ F 04 B 47/00).

 Such a drive can only be used in wells where the loads at the point of suspension of the rods are the same, and balance each other.

 In case of imbalance, the efforts of the fluid pressure developed from the rod cavity of the cylinder with a lower load will not be enough to lift the plunger and the associated rod string of a more loaded well.

 Another group drive of borehole, sucker rod pumps is known, comprising drive cylinders, rod and rodless cavities of which are separated by a piston with a rod having a connection unit with a rod string, and a hydraulic system including a power pump, a controlled hydraulic distributor, and a balancing device in the form of a pneumatic accumulator. USSR copyright certificate 1174594 M. Kl. F 04 B 47/00, 1985).

 Such a group drive, thanks to the balancing device, allows you to create additional balancing force, providing a supply of working fluid to the power pump from the drive cylinder with a lower load, equal to the support from the drive cylinder with a larger load.

 However, the creation of such an additional backwater increases the load on the power pump, increases energy consumption and increases the requirements for sealing units and other elements of the hydraulic system and thus reduces the reliability of the drive.

 The objective of the invention is to provide a drive pumping installation of two pumps with higher reliability, and lower energy consumption during operation in the case when the weight of the rod columns in the wells is different and they do not completely balance each other. To solve this problem, it will improve the drive of a pumping well installation, containing two drive cylinders, rod and rodless cavities of each of which are separated by a piston with a rod having a connection node with a rod string, and a hydraulic system including a power pump, a hydraulic valve, a hydraulic accumulator, and controlled valves.

 This improvement consists in the fact that the pneumatic accumulator is made in the form of a tandem cylinder with a rod with pistons fixed at its ends, and two hydraulic rod cavities, each of which is connected via rod valves to the rod cavities of the drive cylinders and the valve, while rodless cavities of the drive cylinders through the control valve is connected to a power pump and a drain.

 The implementation of the pneumatic accumulator in the form of a tandem cylinder, the pistons are fixed at the ends of the rod, allows one to obtain two hydraulic cavities in which the working fluid pressure can be the same (when both wells are balanced) and different (if the balance is unbalanced) due to the creation of pressure in the gas cavity of the pneumatic accumulator.

 The connection of the hydraulic cavities of the pneumatic accumulator through the controlled valves with the rod cavities of the drive cylinders allows the actuator to create the required (identical or different) fluid pressure in the rod cavities of the drive cylinders (depending on the load on the wells) at a constant pressure created by the power pump. The connection of rodless cavities of the drive cylinders through a distributor with a power pump and a drain provides alternate supply and discharge of fluid from the rodless cavity of the corresponding drive cylinder, which is necessary to move the rods of these cylinders in antiphase during antiphase during operation of the drive.

 The invention is illustrated in the drawing, which shows a schematic hydraulic diagram of the drive of a pumping well.

 The drive of a pumping well installation comprises two drive cylinders 1 and 2, rod 3; 3 'and rodless 4; 4 ', the cavities of each of which are separated by pistons 5; 5 'connected by means of rods 6; 6 ', connected during installation at the well with a rod string (not shown), and a hydraulic system including a power pump 7, a controlled valve 8, controlled valves 9-16, a pneumatic accumulator 17.

 The pneumatic accumulator 17 is made in the form of a tandem cylinder with a jumper 18. Through the hole 18 in the jumper 18 'there is a rod 19 with pistons 20 and 21 at its ends with the formation of two rod hydraulic cavities 22 and 23, each of which is piped 24 through 27 through controlled valves 10 , 11 and 14.15 are connected to the rod cavities 3 and 3 'of the cylinders 1 and 2. The gas cavity 28 of the pneumatic accumulator 17 is connected to a container with compressed gas (not shown in the drawing).

 Rodless cavities 4 and 4 'of the drive cylinders 1 and 2 by pipelines 29 and 30 with valves 9 and 13 are connected through a controlled valve 8 to the power pump 7 and drain 31.

 The valve 8 in the right (according to the drawing) position provides the connection of the rodless cavity 4 of the cylinder 1 with the pump 7, and the rodless cavity 4 'of the cylinder 2 with the drain 31.

 Another, left (according to the drawing) position of the control valve 8 provides the connection of the rodless cavity 4 'of the cylinder 2 with the pump 7, and the rodless cavity 4 of the cylinder 1 with the drain 31.

 The operation of the drive is as follows.

 Before starting work, the rod 6 and the piston 5 of the cylinder 1 are in the upper position. The valve 8 is installed in the right (according to the drawing) position.

 If the weight of the rod columns of both wells is mutually balanced and the load on the drive cylinders 1 and 2 are equal, the pressure equal to atmospheric pressure in the gas cavity 28 of the pneumohydraulic accumulator, the controlled valves 9, 10, 13, 15 are open, 11, 12, 14, 16 are closed . From the pump 7, the working fluid under pressure through the valve 8 through the pipe 29 is fed into the rodless cavity 4 of the cylinder 1, the piston 5 moves under pressure of the fluid along with the rod 6 of the rod string and the plunger of the first well pump (not shown).

 In this case, the liquid from the rod cavity 3 of the cylinder 1 through the pipeline 25 through the open valve 10 enters the hydraulic cavity 22 of the pneumatic accumulator 17, moves up the piston 20 and, connected with it through the rod 19, the piston 21, displacing the liquid from the cavity 23 through the pipeline 26 through the valve 15 into the rod cavity 3 ′ of the cylinder 2. The piston 5 ′ of the cylinder 2 moves upward together with the rod 6 ′ and the rod string of the second well pump (not shown). The working fluid from the rodless cavity 4 'through the pipe 30 through the open valve 13 and the valve 8 is displaced to drain 31. When the piston 5 reaches its lowest position, a switch (not shown) is actuated, moving the valve 8 to the left (according to the drawing) position, while work includes the right half of the control valve 8.

 The drive reverses.

 The fluid from the pump 7 through the pipe 30 enters the rodless cavity 4 'of the cylinder 2, moving the piston 5' together with the rod 6 'and the rod string of the second borehole pump (not shown). The fluid from the rod cavity 3 'through the pipe 26 through the valve 15 enters the hydraulic cavity 23 of the pneumatic accumulator 17, moving down the piston 21 and the associated piston 20, which displaces the fluid from the cavity 22 through the pipe 25 through the valve 10 of the rod cavity 3 of cylinder 1.

 The piston 5 moves up along with the rod 6 and the rod string of the first borehole pump. From the rodless cavity 4 of the cylinder 1 through the pipe 29, the working fluid flows through the open valve 9 and the valve 8 to the drain 31. When the piston 5 reaches its extreme upper position, the switch operates, moving the valve 8 to the right (according to the drawing) position, reversing the drive. After reversing the drive, the duty cycle is repeated.

In the case of drive operation, when the weight of the rod columns is different and they do not completely balance each other, the loads at the half-point of the rod columns to the rods 6 and 6 'of the drive cylinders 1 and 2 are different. For example, the load on the drive cylinder 2 is greater than on the cylinder 1 (G ₁ <G ₂ ).

где
G₁ - нагрузка в точке подвеса колонны штанг, связанных со штоком 6 цилиндра 1;
G₂ -нагрузка в точке подвеса колонны штанг, связанных со штоком 6' цилиндра 2;
S_ц - площадь поперечного сечения цилиндра;
P₃ - давление газа в полости 28;
S_ш - площадь поперечного сечения штока;
P₁ - давление рабочей жидкости в полости 22;
P₂ - давление рабочей жидкости в полости 23.Controlled valves 9-16 are in the position described above, in the gas cavity 28 of the pneumohydraulic accumulator 17 creates pressure
P ₃ = P ₂ - P ₁ ,
Where

Where
G ₁ - load at the point of suspension of the rod string associated with the rod 6 of cylinder 1;
G _{2 -} load at the point of suspension of the rod string associated with the rod 6 'of cylinder 2;
S _c - the cross-sectional area of the cylinder;
P ₃ - gas pressure in the cavity 28;
S _W - the cross-sectional area of the rod;
P ₁ - pressure of the working fluid in the cavity 22;
P ₂ - pressure of the working fluid in the cavity 23.

In the hydraulic cavities 22 and 23 of the pneumatic accumulator 17, due to P ₃ , different pressure P ₂ = P ₁ + P ₃ is created in the cavity 28, which ensures balancing the load on the pistons 5 and 5 '.

 The operation of the drive is similar to that described above.

In the case where the load on the drive cylinder 1 is greater than on the cylinder 2 (G ₁ > G ₂ ), the controlled valves 9, 11, 13, 14 are open, and 10, 12, 15, 16 are closed.

(см. экспликацию выше).Thus, the rod cavity 3 of the cylinder 1 is in communication with the hydraulic cavity 23, and the rod cavity 3 ′ of the cylinder 2 is in communication with the hydraulic cavity 29 of the pneumatic accumulator 17. Pressure is created in the cavity 28 of the latter.
P ₃ = P ₂ -P ₁ ,
Where

(see explication above).

 The rest of the operation of the drive is similar to that described above.

 In the case of stopping work at one of the wells, the drive ensures that the other well operates in a single mode.

 For example, the left (according to the drawing) part of the drive with a hydraulic cylinder works. Valves 9, 11, 16 are open, and 10 - 15 are closed. The valve is in the right (according to the drawing) position and ensures that the pipe 29 connects the rodless cavity 4 of cylinder 1 to the pump, and the hydraulic cavity 22 of the pneumatic accumulator 17 via pipe 30 through valve 16 and valve 8 with drain 31.

 Another position of the valve 8 provides the connection of the cavity 4 with the drain 31, and the hydraulic cavity 22 of the pneumatic accumulator 17 with the pump 7.

 Before starting work, the rod 6 and piston 5 of the cylinder 1 and the pistons 20 and 21 of the pneumatic accumulator 17 are in the upper (according to the drawing) position.

In the cavity 28 of the pneumatic accumulator 17, a pressure P _{3 is created} to balance the load at the point of suspension of the rod string. The working fluid from the pump 7 through the valve 8 through the pipe 29 through the valve 9 enters the cavity 4 of the cylinder 1 and moves down the piston 5 with the rod 6.

 The fluid from the cavity 3 of the cylinder 1 through the pipe 24 through the valve 11 flows into the cavity 23 of the pneumatic accumulator 17, putting pressure on the piston 21, which moves down and pulls the piston 20, which in turn displaces the fluid from the cavity 22 through the pipe 30 through the valve 16 and valve 8 to drain 31. When the rod 6 reaches its lowest position, a switch (not shown) is actuated, moving valve 8 to the left (according to the drawing) position, while the right half of valve 8. is turned on. of liquid from the pump 7 through the valve 8 through the pipe 30 through the valve 16 enters the cavity 22 of the pneumatic accumulator 17, the piston 20 rises and through the rod 19 pulls the piston 21, which, rising, displaces the working fluid from the cavity 23 through the pipe 24 through the valve 11 into the rod cavity 3 of cylinder 1. Under pressure of this fluid, the piston 5 of cylinder 1 rises and pulls the rod 6 and the rod string of the well pump along with it, and the liquid from the cavity 4 of cylinder 1 through pipeline 29 through valve 9 and valve 8 is displaced to 31.

 When the rod 6 reaches its extreme upper position, a switch (not shown) is activated, moving the valve 8 to the right (according to the drawing) position and the drive operation cycle is repeated.

 The proposed drive design ensures the operation of the installation with two borehole pumps regardless of their mutual imbalance, as well as operation when one borehole pump is switched off with the power pump and its drive operating unchanged.

Claims (1)

 A drive of a pumping downhole installation containing two drive cylinders, the rod and rodless cavities of which are separated by a piston with a rod having a connection node to the rod string, and a hydraulic system including a power pump, a hydraulic distributor, a pneumatic accumulator, controlled valves, characterized in that the pneumatic accumulator is made in the form of a tandem cylinder with a rod with pistons fixed at its ends and two hydraulic rod cavities, each of which is connected to currents in the cavities of the drive cylinders, while the rodless cavities of the drive cylinders are connected through a distributor to the power pump and the drain.