RU2303709C1 - Pump for handling liquid medium - Google Patents

Abstract

FIELD: oil producing industry; positive displacement hydraulic machinery.

SUBSTANCE: invention relates to piston machines and it can be used for handling viscous and nonhomogeneous liquids, mainly, for maintaining formation pressure at producing of oil. Proposed pump for liquid medium contains tandem cylinder with rod and pistons dividing it into four spaces. First and second spaces, being rod ones, are connected through hydraulic distributor with pump and drain of working component. Spaces for liquid medium are connected with inlet and delivery lines of liquid medium provided with check valves. Pump has two additional reservoirs, each being divided by piston into two spaces, first of which are spaces for liquid medium and second spaces of first and second additional reservoirs are connected, second space of first and second additional reservoirs through hydraulic distributor with pump and drain of working component parallel to first and second rod spaces of tandem cylinder, respectively. Each pipeline of leakage compensation system is furnished with two check valves pointed in opposite directions, one of which is installed in wall of second space of additional reservoir with possibility of opening at interaction with piston of corresponding additional reservoir.

EFFECT: reduced requirements to pump delivering working component, improved conditions of operation of tandem cylinder pistons.

3 cl, 1 dwg

Description

The invention relates to hydraulic machines for volume displacement, more specifically, to reciprocating machines with a drive, and can be used for pumping viscous and heterogeneous liquids, mainly to maintain reservoir pressure during oil production.

A device for the hydraulic transportation of materials (ed. Certificate No. SU 1652245, IPC ⁵ B65G 53/30, publ. 1991), containing two containers with dividers of internal volume in the form of elastic diaphragms, pipelines with non-return valves for supplying and discharging transported media and pipelines for supplying and discharging the working component, connected to tanks on different sides of the separator.

The disadvantage of this device is its low efficiency when it is used for transporting liquid under pressure, which is explained by the autonomous operation of the containers and the need to use a powerful source of pressure of the working medium.

Closest to the claimed and adopted as a prototype is a liquid pump (RU No. 22201, IPC ⁷ F04B 9/10, publ. 2002), containing a tandem cylinder with a rod with pistons dividing it into four cavities, of which the first and the second - rod connected through the valve with the pump and the discharge of the working component, as well as the cavity for the fluid, connected to the inlet and discharge lines of the fluid with check valves.

During the operation of such a pump for transporting a pressurized fluid, at the suction stroke, the pressure of the working component in the pressure line is the sum of the pressure created by the pump of the working component and the pressure of the fluid at the pump inlet, which partially improves the efficiency of the pump.

However, such a pump, when transporting a pressurized fluid at the discharge stroke, also requires the use of a working component pump that creates a pressure higher than the pressure in the fluid inlet line, which increases the cost of the pump and reduces its efficiency. In addition, the tandem cylinder pistons operate in an aggressive, contaminated fluid environment, which reduces the reliability of the pump and necessitates frequent replacement of the sealing elements.

The objective of the invention is to increase the efficiency of the pump by reducing the requirements for the feed pump of the working component and increasing the reliability by improving the working conditions of the tandem cylinder pistons.

The problem is solved due to the fact that in the design of the pump containing a tandem cylinder with a rod with pistons dividing it into four cavities, of which the first and second rod are connected through a valve with a pump and a discharge of the working component, as well as the cavity for the fluid, connected to the inlet and discharge lines of the fluid with check valves, distinguishing features are introduced.

These signs are: the pump contains two additional containers, each of which is divided by the piston into two cavities, the first of which are cavities for the fluid, and the second cavities of the first and second additional containers are connected respectively to the third and fourth - piston cavities of the tandem cylinder with the formation of two closed hydraulic circuits having a leakage compensation system made in the form of two pipelines connecting the second cavity of the first and second additional tanks through the hydraulic circuit A valve with a pump and a discharge of the working component parallel to the first and second rod cavities of the tandem cylinder, respectively, and each pipeline of the leakage compensation system is equipped with two oppositely directed non-return valves, one of which is installed in the wall of the second cavity of the additional tank with the possibility of opening the corresponding additional tank when interacting with the piston .

In addition, in each additional tank, the cavities can be interconnected by a channel with a check valve that opens when the pressure in the second cavity is higher than the pressure in the first.

In addition, the channel with a check valve connecting the cavity of each additional tank can be made in its piston.

The supply of the pump with two additional tanks, each of which is divided by a piston into two cavities, the first of which are cavities for a fluid, and the second cavities of the first and second additional tanks are connected respectively to the third and fourth - piston cavities of the tandem cylinder, allows you to sum the pressure in the tandem cylinder created by the pump of the working component with the pressure of the fluid in its inlet line, which allows the use of a less powerful pump of the working component, to reduce the requirements for sealing itelnym elements tandem cylinder pistons, as they operate in a lower pressure drop. In addition, with this design, the pump eliminates the contact of the tandem cylinder pistons with aggressive, contaminated fluid, which also increases the reliability of the pump.

Providing closed hydraulic circuits with a leakage compensation system made in the form of two pipelines connecting the second cavity of the first and second additional tanks through the valve with the pump and draining the working component parallel to the first and second rod cavities of the tandem cylinder, respectively, and supplying each pipeline of the leakage compensation system with two oppositely directed check valves, one of which is installed in the wall of the second cavity of the additional capacity with the possibility of covering of the interaction with the piston corresponding additional capacitance provides feeding the working component in a closed hydraulic circuit only when the gap.

The connection in each additional capacity of the cavities with each other by a channel with a non-return valve, which opens when the pressure in the second cavity is higher than the pressure in the first, eliminates the overflow of the second cavity of each tank by dumping part of the working component from the second cavity of the first tank into the first and line fluid injection, while the valve operates in a small pressure drop, which reduces the requirements for it.

The implementation of the channel with a check valve connecting the cavity of each additional tank in its piston is a rational design option.

The invention is illustrated in the drawing, which shows the hydraulic circuit of the proposed device.

The fluid pump contains a tandem cylinder 1 with a rod 2 with pistons 3 and 4 dividing it into four cavities 5, 6, 7 and 8, of which the first 6 is connected by a pipe 9 and the second rod 7 is connected through a valve 10 to a pump 11 and a drain 12 working components. The pump contains two additional tanks 13 and 14, separated by pistons 15 and 16 into two cavities - the first tank 13 is divided into cavities 17 and 18, and the second tank into cavities 19 and 20. Cavities 17 and 19 are cavities for a fluid medium. The second cavity 18 of the first additional tank 13 is connected to the third piston cavity 5 of the tandem cylinder 1 with the formation of the first closed hydraulic circuit. The second cavity 20 of the second additional tank 14 is connected to the fourth piston cavity 8 of the tandem cylinder 1 with the formation of a second closed hydraulic circuit. Closed hydraulic circuits have a leakage compensation system made in the form of two pipelines 21 and 22 with two oppositely directed check valves 23 and 24 (in the pipeline 21), 25 and 26 (in the pipeline 22). The pipe 21 connects the second cavity 18 of the first additional tank 13 through the valve 10 with the pump 11 and the discharge 12 of the working component parallel to the first rod cavity 6 of the tandem cylinder 1. The pipe 22 connects the second cavity 20 of the second additional tank 14 through the valve 10 with the pump 11 and the drain 12 of the worker component parallel to the second rod cavity 7 of the tandem cylinder 1. Valves 24 and 26 are installed in the wall (in the above embodiment, in the end wall 27 and 28) of the second cavities 18 and 20 of additional containers 13 and 14 with the possibility of opening, in cooperation with the pistons 15 and 16, the corresponding additional tank 13 and 14. In the above embodiment, the cavities 17 and 18 of the tank 13 are interconnected by a channel 29 with a check valve 30, and the cavities 19 and 20 of the tank 14 are connected by a channel 31 with a check valve 32 The valve 31 opens when the pressure in the second cavity 18 is higher than the pressure in the first cavity 17. The valve 32 opens when the pressure in the second cavity 20 is higher than the pressure in the first cavity 19. Channel 29 with valve 30 and channel 31 with valve 32 in the depicted cx IU formed in the pistons 15 and 16 (which may be in the form of pipelines). The cavity 17 is connected to the inlet line 33 with a non-return valve 34 for supplying a fluid and a discharge line 35 with a non-return valve 36 for discharging a fluid. The cavity 19 is connected to the inlet line 37 with a check valve 38 for supplying a fluid and a discharge line 39 with a check valve 40 for discharging a fluid.

The proposed pump operates as follows.

In the initial position (shown in the drawing), the first container 17 is filled with transported fluid (for example, a solution to maintain reservoir pressure) entering the cavity 17 through the pipe 33 through the open valve 34. From the pump 11, the working component through the valve 10 is fed into the rod cavity 7 tandem cylinder 1. In this case, the piston 4 and the associated piston 3 move to the right according to the drawing, displacing the working component from the cavity 5 through the pipeline into the cavity 18, moving the piston 15 and displacing the fluid from the cavity 17 into the discharge pipe 35 through the opening valve 36. At the same time, when the piston 3 moves, the volume of the cavity 8 increases, into which the working component is sucked out of the cavity 20. The piston 16 of the container 14 moves upward, increasing the volume of the cavity 19, opening the check valve 38, and along the input line 37, the fluid enters the cavity 19. In the tandem cylinder 2, the pressure created by the pump 11 of the working component is added to the pressure of the fluid in the input line 37. When the pistons 3, 4 and the rod 2 move to the right, the working component is displaced from the cavity 6 through the pipeline 9 through the valve 10 to the drain 12. When the pistons 3 and 4 reach the extreme right position, the flow switches (the switch is not shown), and the working component from the pump 11 through the valve 10 through the pipe 9 is fed into the cavity 6 of the tandem cylinder 1 , providing movement of the rod 2 and pistons 3 and 4 to the left. In this case, the cavity 19 is filled with fluid through the pipe 37 through the open check valve 38 and the fluid is displaced from the cavity 17 through the open valve 36 through the pipe 35. In the tandem cylinder 2, the pressure created by the pump 11 of the working component is summed with the pressure of the fluid in the inlet line 33. When the pistons 3 and 4 reach the extreme left position, the pump cycle is repeated, while ensuring a constant flow of fluid into the common discharge line 41.

With a decrease (due to leaks) in the volume of fluid in the first closed hydraulic circuit (cavities 5 and 18) and in the second circuit (cavities 8 and 20), the movement zone of the pistons 15 and 16 is shifted upward in the drawing. And the pistons 15 and 16 in the upper position interact with the locking elements of the corresponding non-return valves 24 and 26, opening them and ensuring the working component enters the cavity 18 from the pump 11 through the pipe 21 through the valves 23 and 24, and into the cavity 20 from the pump 11 22 through valves 25 and 26. When switching the control valve 10, the valves 23 and 25 are closed, preventing the draining of the working component from the corresponding closed hydraulic circuits. Thus, the feed of the working component into closed hydraulic circuits occurs only when it is lacking.

In the case of using the proposed pump for pumping a fluid, when the pressure in the cavities 17 and 19 is less than the pressure created by the pump 11, overflow of the cavities 18 and 20 with the working component can occur due to leaks, which will lead to the pistons 15 and 16 coming to the bottom containers 13 and 14 and increasing the pressure in the cavities 18 and 20. Under the influence of this pressure, the valves 30 and 32 will open and excess working component through the channels 29 and 31 will flow into the cavities 17 and 19, respectively.

Thus, the use of the proposed pump allows to increase the efficiency of pumping fluid by reducing the requirements for the pump supply of the working component, increase the reliability by improving the working conditions of the pistons of the tandem cylinder, eliminating the need to stop the pump due to leakage of the working component.

Claims (3)

1. A fluid pump containing a tandem cylinder with a rod with pistons dividing it into four cavities, of which the first and second are rod connected through a valve with a pump and a discharge of the working component, as well as fluid cavities connected to the inlet and discharge fluid lines with check valves, characterized in that it contains two additional containers, each of which is divided by a piston into two cavities, the first of which are cavities for the fluid, and the second cavities of the first and W A number of additional tanks are connected respectively to the third and fourth piston cavities of the tandem cylinder with the formation of two closed hydraulic circuits having a leakage compensation system made in the form of two pipelines connecting the second cavity of the first and second additional containers through the valve with the pump and the discharge of the working component parallel to the first and the second rod cavities of the tandem cylinder, respectively, and each pipeline of the leakage compensation system is equipped with two prot opposite directional check valves, one of which is installed in the wall of the second cavity of the additional capacity with the possibility of opening in cooperation with the piston of the corresponding additional capacity. 2. The pump according to claim 1, characterized in that in each additional capacity the cavities are interconnected by a channel with a check valve, which opens when the pressure in the second cavity is higher than the pressure in the first. 3. The pump according to claim 1, characterized in that the channel with a check valve connecting the cavity of each additional tank is made in its piston.