RU2347945C1 - Oil pumping station - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention is applicable to the oil and gas producing industry and petrochemical industry and particularly to oil and gas transportation and processing and can be implemented at oil pumping stations and plants including in oil fields and oil refineries. The oil pumping station has a network of station utilities including oil or probably petroleum product and gas condensate forming at least one hydraulic system, and process pipelines equipped with shutoff and/or shutoff and control valves with a locking mechanism. Pumping equipment includes a group of main pressure pumps, a group of boosting pumps, as well as a storage tank battery at the entrance or at least one station tank; a connection unit to connect to the external product supply trunk pipeline and/or storage tank battery and oil metering station with filters; a pressure control unit, safety devices, cleaning devices; a receiver/starter unit for the said devices and diagnostic tools. There is also an electrical substation, a system of cold and/or hot water supply and industrial and domestic wastewater drain devices and pipelines, and a boiler house with heat supply pipework. At least one pressure process pipeline and/or hydraulic pipeline for water or heat supply to the said facilities is equipped with at least one hydromechanical mechanism to provide gradual load of the hydraulic system. It is connected to at least one pressure pipeline usually on the pressure side so that on and off operations of the shutoff and/or shutoff and control valves can be automatically prolonged. The hydromechanical device includes the following components that are connected in series with each other: an inlet nozzle; a governor to control the opening speed of the shutoff and/or shutoff and control valves and the load transfer to the hydraulic system; and hydromechanical drive. The latter includes a power chamber with a housing containing at least one variable displacement compartment and a transfer mechanism. The hydromechanical device is double-connected to the pipeline: at the inlet - an inlet nozzle allows it to communicate with the pipeline through working medium; at the outlet - it is kynematically connected by the hydromechanical drive with the locking element of the above-mentioned valves. The movable transfer mechanism is connected to the power chamber through a "piston-rod" or "membrane-rod" connection type. This reduces power inputs for hydraulic systems providing operation of oil pumping station systems.

EFFECT: reduced maintenance and repair costs.

23 cl, 11 dwg

Description

The invention relates to the field of oil and gas and petrochemical industries, in particular to the transportation and processing of oil and gas, and can be implemented at oil pumping stations and plants, including oil fields and oil refineries.

From the prior art there is known a method of starting a centrifugal electric drive pump unit or units operating according to a serial connection scheme at pumping stations of main pipelines for pumping oil products (RU 2263824 C2, 10.11.2005).

From the prior art, a known installation for transfusion of liquids from several tanks at distribution depots (SU 1616856 A1, 12/30/1990). The installation contains drain pipelines with valves connected to the collector and reservoirs; the installation is controlled by an electronic computer connected to flowmeters. To protect the flow meters from water hammer, the locking elements can be equipped with rods with tips. This device reduces the impact of water hammer, but does not completely exclude it.

The technical problem to which the present invention is directed is to provide the necessary level of safety and reduce energy consumption during operation of both individual hydraulic and / or pumping systems of an oil pumping station containing incompressible liquids or mixtures, and the oil pumping station as a whole, as well as a significant reduction in costs equipment repair and maintenance.

The problem is solved due to the fact that the oil pumping station according to the invention contains a network of in-plant communications, including communicated via the pumped product - oil or possibly oil and gas condensate - forming at least one hydraulic system process piping equipped with a shut-off element and / or shut-off and control valves, pumping equipment, including a group of main pressure pumps, mainly with electric drive and, in particular, a group of booster pumps, as well as, preferably, a tank fleet equipped at the inlet or at least one tank of the station, a unit for connecting to the product supply external piping and / or a tank fleet, preferably an oil metering unit with filters, a unit pressure regulation, safety devices, treatment devices, equipped with start-up and reception chambers for treatment devices and collection of selected contaminants, the receiving-starting unit of these devices and diagnostics, electrical a station, a set of devices and pipelines for cold and / or hot water supply of a station, an outlet for industrial and domestic wastewater, a boiler room with networks of heat supply pipelines, at least one pressure-filled process pipeline and / or a pipeline of a hydraulic water supply or heat supply network of said oil pumping facilities the station is equipped with at least one hydromechanical device for smooth loading of the hydraulic system connected to at least one pressure head pipeline, mainly on the pressure side in the area between the pump or pump group that creates the pressure in the pipeline and the closest shut-off and / or shut-off and control valves connected to the pipeline through the working fluid, mainly through the pumped liquid and mounted with the possibility of automatic prolonged switching on and shut-off of shut-off and / or shut-off and control valves, while the hydromechanical device includes an inlet pipe in series connected to each other, having a housing with a speed regulator for opening the shut-off and / or shut-off and control valves and transferring the load to the hydraulic system equipped with a check valve and a nozzle, and a hydromechanical drive, including a power chamber with a housing containing at least one compartment with a variable displacement, adjustable back filled with a fluid working fluid with increasing pressure in the pipeline, and the transmission mechanism, while connecting to the pipeline of the hydromechanical device is double: at the inlet - inlet pipe but it is communicated with the pipeline through the working fluid, and at the outlet, by a kinematically hydromechanical drive with a locking element of the mentioned fittings, the transmission mechanism is movable, connected to the power chamber by the piston-rod or membrane-rod type, with the rod in turn, it is movably connected with the formation of a drive with a locking element of the aforementioned valves with the possibility of automatic movements of the locking element in the range from full overlap to the pipeline completely open to the duct, and vice versa.

In this case, the network of in-plant communications and, primarily, forming the main hydraulic system of the oil pumping station of technological pipelines, connecting the external main pipeline with a group of main pressure pumps and, if available, with a group of booster pumps, as well as adjustable with a possible tank farm or station tank, can be mounted with the possibility of implementing the technology of pumping from pump to pump, including switching off tanks for the period of operation of this technology and their availability, and the aforementioned hydromechanical smooth load device is mounted on the pressure section of the pipeline after the corresponding pump group.

A network of in-plant communications and, primarily, forming the main hydraulic system of the oil pumping station of technological pipelines that connect the external main pipeline to a group of main pressure pumps and, if available, to a group of booster pumps, can be mounted with the possibility of implementing on-site technology for pumping oil or oil products, or gas condensate why the oil pumping station is equipped with at least two tanks, and the tank lining and the system locking displacements or shut-off control valves are mounted with the possibility of providing alternately pumped into one of said tanks, and at the same time independent injection of said product into the pipeline from another tank.

The network of in-plant communications and, primarily, those that form the main hydraulic system of the oil pumping station of technological pipelines that connect the external main pipeline with a group of main pressure pumps and, if available, with a group of booster pumps, can be mounted with the possibility of implementing pumping technology with connecting tanks, and the hydraulic system of technological pipelines of the station are mounted either by appropriate switching of the shut-off and / or shut-off and full-time valves are configured with the ability to pump oil, oil product or gas condensate entering the station and pump by main pressure or booster pumps to the subsequent section of the external main pipeline through the same tank of the station.

The hydraulic system of the plant’s process pipelines can be mounted or adjusted by appropriate switching of shut-off or shut-off and control valves with the ability to pump oil, oil product or gas condensate entering the station and pump by main pressure and / or booster pumps to the subsequent section of the external main pipeline, mainly bypassing the reservoir fleet with the possibility of compensating for unbalances by dumping or pumping part of the oil, at least to one of the reservoirs of the station.

At least part of the main pressure pumps of the station can be mounted sequentially with the possibility of increasing the generated pressure at the outlet of the corresponding group of pumps and in the subsequent section of the external main pipeline, including exceeding the possible technical capacity to create the pressure of any individual pump from the specified group.

The group of main pressure and / or booster pumps can be switched in the hydraulic system of the station in parallel or in a combined series-parallel circuit through an additional collector.

An oil pumping station may include an engineering and laboratory building, a fire station, facilities for setting up and repairing instrumentation, a communication and control station, and a receiving and starting unit for purification devices and diagnostic tools is mounted and connected to the hydraulic system of the station and an external trunk pipeline with the possibility of receiving the said funds from the limit switches of the pipeline section preceding in the product supply direction and launching the mentioned section into the initial zone of the subsequent section removed trunk pipeline.

The oil pumping station can be made head on the main pipeline or on its production site and is equipped with a tank farm included in the hydraulic system of the station by strapping technological pipelines, made at least partially single-wire or two-wire with the possibility of simultaneously filling two and two products arriving at the station more tanks or one of them, and at the same time with the possibility, including simultaneously performed sampling through those e and / or other reservoirs, wherein at least one said smooth load hydraulic hydromechanical device mounted at the outlet of the pressure generating one or group of pumps.

The aforementioned non-return valve and nozzle can be placed in the body of the speed controller for opening the mentioned valves, the nozzle and non-return valve being structurally combined.

The check valve of the opening speed controller of said valve may contain a rod having a passage with outlet openings with a damper made at one end and a nozzle at the other end, including a regulating screw, preferably a screw element inserted into the check valve’s passage through the check valve measure of partial overlap of the passage section of the passage channel - the passage hole for its calibration using the nozzle of the nozzle, which is equipped with a screw element, by changing its position about regarding the throughput channel.

The speed controller for the opening of said reinforcement can be equipped with a return device associated with a check valve and / or nozzle and made, for example, in the form of a spring.

The speed controller for the opening of said reinforcement can be equipped with a return device mounted on the screw element of the nozzle and made, for example, in the form of a spring.

The body of the speed controller for opening the shut-off and / or shut-off and control valves may contain at least three compartments, in the first compartment there is a check valve flap with an inlet of the passage channel made in it, in the second compartment at least partially the return rod is located the valve and at least one outlet opening of the passage channel, made in the rod, in the third compartment there is a screw element of the nozzle and a return device of the opening speed controller, while the second compartment is connected n of the working fluid to the power chamber and the opening in the housing of the speed controller in the third compartment an opening closed by a screw plug for adjusting the flow cross section of the passageway through the screw member.

To change the position of the nozzle needle relative to the passage hole, the nozzle can be equipped with a calibration device that can be manually adjusted from the outside of the body of the speed controller for opening the shut-off and / or shut-off and control valves.

The power chamber may be provided with a sealed elastic membrane separating the power chamber body into said compartment with a variable working volume and a compartment which is not filled by the working fluid, the membrane being made with the possibility of alternating deformation directed depending on the pressure both towards the filled compartment and in the side of the non-fillable compartment of the power chamber, and in the non-fillable compartment of the power chamber a hole is made with a guide sleeve fixed therein, providing translational e movement of the gear mechanism.

The hydromechanical device may be provided with a return device hydromechanical drive associated with the transmission mechanism and / or the membrane of the drive and made, for example, in the form of a spring.

The power chamber may be provided with a piston dividing the power chamber housing into said compartment with a variable working volume filled with a working fluid and a compartment that is not filled with it and made with the possibility of movement in the power chamber depending on the pressure change, and an opening is fixed in the non-filled compartment of the power chamber with him guiding sleeve, providing translational movement of the gear mechanism.

Shut-off and / or shut-off and control valves can be made with a spindle having a shut-off element, and the transmission mechanism consists of at least two elements, the first element - the rod - of the transmission mechanism through a safety pad connected to the membrane of the power chamber, and the second the element is connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter.

The first and second elements of the transmission mechanism can be made rectilinear and interconnected movably, for example, articulated, moreover, in the second element at the junction of it with the first there is a hole inside which there is a pin connecting both of these elements, and the second element of the transmission mechanism is made with the ability to rotate from 0 to 90 degrees from the starting position, while 0 degrees corresponds, for example, to a completely closed reinforcement, and a value of 90 degrees corresponds to a fully open one.

Shut-off and / or shut-off and control valves may be a valve, for example, a ball valve.

The transmission mechanism interacting with the shut-off and / or shut-off and control valves can be made in the form of a lever or a crank mechanism, or a gear rack.

The maximum throughput of the non-return valve of the valve of the speed of opening of said armature can be at least two times higher than the maximum throughput of the nozzle.

The technical result achieved when using the claimed invention is to ensure safety and reduce energy consumption during the operation of hydraulic systems that ensure the operation of oil pumping station systems containing incompressible liquids, reducing the cost of repair and maintenance of equipment due to reduced load on the elements of the hydraulic system - shut-off and / or shut-off -adjusting valves, pipelines and pumping equipment, which is achieved by the combination developed in the invention significant features that create a cumulative positive effect exceeding the sum of the input effects from individual elements of the invention, namely, the location of the communication between the pumps and the shutoff and control valves, which are connected with the pipelines along the working fluid or the working medium, allows the pumps to be turned on and a set of revolutions close to workers, with the valves closed, which reduces energy consumption when starting the electric motors of the pumps, and the sequence of location and the proposed structural The solutions of the opening speed controller and the hydromechanical valve drive provide, on the one hand, the automatically achieved smoothness of opening the valves and turning on the hydraulic systems, and, on the other hand, provide a quick release of pressure in the device and shutting down the systems when the engines are turned off. The latter is achieved due to the adjustable ratio of the inlet nozzle and non-return valve flow rate proposed in the invention, as well as due to the implementation of an elastic-flexible separation membrane installed in a rigid power chamber, which ensures smooth movement of the hydromechanical actuator transmission mechanism in the valve opening mode and faster but also smooth closing, reinforced by tripping in reverse mode due to the additional energy of the spring travel amplifier. This together creates the necessary smoothness and adjustable speed of the device, as well as cost-effectiveness, the possibility of both autonomous and joint work with other devices in the hydraulic systems of the oil pumping station.

The technical solution is illustrated by drawings, which show a special case of a hydromechanical device, not covering, and even more so, not limiting the entire scope of the claims of this solution, where:

figure 1 shows a hydromechanical device connected to the pipeline with a power chamber provided with a sealed elastic membrane (working fluid or working medium is not shown);

figure 2 is connected to the pipeline hydromechanical device with a power chamber equipped with a piston (working fluid or working medium is not shown);

figure 3 - speed controller for the opening of shut-off and / or shut-off and control valves with screwed-off plug;

figure 4 - power chamber with a sealed elastic membrane;

figure 5 - hydromechanical device at the beginning of the process of opening the mentioned valves - the pump motor in the phase of exit from idle to operating revolutions;

figure 6 - hydromechanical device with a fully open mentioned valves - the engine in the phase of operation at full power;

Fig.7 - hydromechanical device after the end of the pressure - with the engine turned off;

on Fig - hydromechanical device in an embodiment with an intermediate (additional) working fluid;

figure 9 - hydromechanical device in an embodiment with several intermediate (additional) working bodies;

figure 10 is an embodiment of a hydromechanical device with a transmission mechanism in the form of gear racks and wheels.

11 is a diagram of a hydraulic system for pumping fluid with a hydromechanical device.

An oil pumping station (not shown in the drawings) contains a network of in-plant communications, including those communicated by the pumped product — oil or possibly oil product and gas condensate — that form at least one hydraulic system 1, process pipelines 2 equipped with a shut-off element and / or shut-off and control valves 3, pumping equipment, including a group of main pressure pumps 4, mainly with an electric drive and, preferably, a group of booster pumps (n not shown), and also, preferably, a tank farm equipped at the inlet or at least one tank of the station, a unit for connecting to the product supply external piping and / or tank farm, preferably an oil metering unit with filters, unit pressure control, safety devices, treatment devices, equipped with start-up and reception chambers for treatment devices and collection of selected contaminants, receiving-starting unit of these devices and diagnostic tools, electrical substation, comp a lex of devices and pipelines for cold and / or hot water supply to the station, the discharge of industrial and domestic wastewater, a boiler room with networks of heat supply pipelines (not shown in the drawings).

At least one pressure line process pipe 2 and / or a hydraulic or water supply pipe of said oil pumping station facilities is equipped with at least one hydromechanical device 5 for smooth loading of the hydraulic system connected to at least one pressure pipe 2, mainly from the pressure side in the area between the pressure pump 4 or the pump group and the closest shut-off and / or shut-off and control arm uroy 3 communicating with the conduit 2 through the working fluid 6, advantageously pumped fluid and mounted with the possibility of automatic switching on and off a prolonged shut-off and / or shut-off and control valves 3.

Said hydromechanical device 5 includes an inlet pipe 7 connected in series with one another, having a body 8 of an opening speed controller 9 for shut-off and / or shut-off and control valves 2 and for transferring the load to the hydraulic system 1, equipped with a check valve 10 and a nozzle 11, and a hydromechanical drive 12, including a power chamber 13 with a housing 14 containing at least one compartment 15 with a variable displacement, adjustable refillable with a liquid working fluid 6 with increasing pressure in the pipeline 2, and the transmission mechanism 16. The connection to the pipeline 2 of the hydromechanical device 5 is double: at the inlet - with the inlet pipe 7 it is connected with the pipe 2 through the working fluid 6, and at the exit - with a kinematically hydromechanical actuator 12 with a locking element of the mentioned valve 3.

The transmission mechanism 16 is made movable, connected to the power chamber 13 of the type "piston-rod" or "membrane-rod". The rod 17, in turn, is movably connected with the formation of the actuator with the locking element of the shut-off and / or shut-off and control valves 3 with the possibility of automatic movements of the locking element in the range from full overlap to the pipeline 2 completely open to the duct, and vice versa.

The in-plant communication network and, primarily, forming the main hydraulic system 1 of the oil pumping station of the technological pipelines 2, connecting the external main pipeline with a group of main pressure pumps 4 and, if available, with a group of booster pumps, as well as adjustable with a possible tank farm or station tank, is mounted with the possibility of implementing the technology of pumping from pump to pump, including switching off reservoirs for the period of operation of this technology when they are empty PIR, and said hydromechanical device 5 is mounted on the smooth load discharge pipe section 2 after the corresponding pumping group.

An in-plant communication network, and primarily, forming the main hydraulic system 1 of an oil pumping station of technological pipelines 2, connecting an external main pipeline with a group of main pressure pumps 4 and, if available, with a group of booster pumps, is mounted with the possibility of implementing on-site technology for pumping oil or oil products, or gas condensate, for which the oil pumping station is equipped with at least two tanks (not shown in the drawings), and the piping tanks and a system for placing shut-off or shut-off and control valves 3 are mounted with the possibility of alternating pumping into one of the mentioned tanks and at the same time independent pumping of the mentioned product into the main pipeline from another tank.

The in-plant communication network and, primarily, forming the main hydraulic system 1 of the oil pumping station of technological pipelines 2, connecting the external main pipeline with a group of main pressure pumps 4 and, if available, with a group of booster pumps, is mounted with the possibility of pumping technology with connecting tanks, and the hydraulic the system 1 of technological pipelines of 2 stations is mounted either by appropriate switching of the shut-off and / or shut-off and ovochnoy armature 3 is configured to pump crude oil coming into the station, petroleum or gas condensate and pump pressure head or trunk booster pump in a subsequent portion of the outer main pipe through one and the same tank station.

The hydraulic system 1 of the technological pipelines of 2 stations is mounted or, by appropriate switching of shut-off or shut-off and control valves 3, is configured to pump oil, oil product or gas condensate entering the station and pump by main pressure and / or booster pumps to the subsequent section of the external main pipeline, mainly bypassing tank farm while maintaining the ability to compensate for unbalances by dumping or pumping part of the oil into at least one of tanks station.

At least a part of the main pressure pumps of the station are mounted in series with the possibility of increasing the generated pressure at the outlet of the corresponding group of pumps and in the subsequent section of the external main pipeline, including exceeding the possible technical capacity to create the pressure of any individual pump from the specified group.

The group of main pressure and / or booster pumps is connected in the hydraulic system 1 of the station in parallel, or in a combined series-parallel circuit through an additional collector.

The oil pumping station includes an engineering and laboratory building, a fire station, facilities for setting up and repairing instrumentation, a communication and control station (not shown in the drawings), and a receiving and starting unit for treatment devices and diagnostics is mounted and connected to the hydraulic system of the station and an external main pipeline with the possibility of receiving the above funds from the limit switches of the previous section of the main pipeline preceding in the direction of product supply and launching into the initial zone molding portion of said main pipeline.

The oil pumping station can be made head on the main pipeline or on its production site and is equipped with a tank farm included in the hydraulic system 1 of the station by strapping technological pipelines 2, made at least partially single-wire or two-wire with the possibility of simultaneous filling with the product entering the station at the same time two or more tanks, or one of them, and at the same time with the possibility, including simultaneously performed sampling through the same and / or other tanks, and at least one of the aforementioned hydromechanical smooth load device 5 of the hydraulic system 1 is mounted at the outlet of the pressure generating one or a group of pumps 4.

In the hydromechanical device 5 in the housing 8 of the opening speed controller 9 of the shut-off and / or shut-off and control valves 3, the aforementioned check valve 10 and the nozzle 11 are located, the nozzle 11 and the check valve 10 being structurally combined. The check valve 10 of the opening speed controller 9 of said valve 3 comprises a passage 18 with outlet openings 19, 20, a stem 21 with a shutter 22 made at one end thereof, and a nozzle 11 at the other end, including a control element, preferably a screw element 23, introduced into the passage channel 18 of the rod 21 of the check valve 10 with the possibility of at least partially blocking the passage section of the passage channel - the passage hole for its calibration - partial overlapping using the needle 24 of the nozzle, which is equipped with a screw element 23, by changing its position relative to the passage channel, in addition, the opening speed controller 9 of the said valve is equipped with a return device 25 connected to the check valve 10 and / or the nozzle 11 and made, for example, in the form of a spring.

The housing 8 of the speed controller opening 9 shut-off and / or shut-off and control valves 3 contains at least three compartments. In the first compartment 26, a check valve 10 is located 22 with an inlet 27 of the passage channel 18 formed therein. In the second compartment 28, at least partially the check valve stem 21 and at least one outlet orifice 19 or 20 are located channel 18, made in the rod 21. In the third compartment 29 there is a screw element 23 of the nozzle 11 and the return device 25 of the opening speed controller 9 of the valve 3. The second compartment 28 is connected via a working fluid 6 to the power chamber 13, and in the housing 8 of the opening speed controller 9 mentioned reinforcement 3 in the region of the third compartment 29, a hole 30 is made, closed with a screw plug 31 to provide adjustment of the flow area of the calibrated hole 32 of the passage channel 18 by means of a screw element.

To change the position of the needle 24 of the nozzle 11 relative to the calibrated hole 32, the nozzle 11 is equipped with a calibration device, for example, a screw element 23, made with the possibility of manual adjustment from the outside of the housing 8 of the opening speed controller 9 of the shut-off and / or shut-off and control valves 3.

The power chamber 13 is provided with a sealed elastic membrane 33 separating the housing 14 of the power chamber 13 into said compartment 15 with a variable working volume and a compartment 34 not filled by the working fluid 6. The membrane 33 is made with the possibility of alternating deformation, directed depending on the pressure as to the side filled compartment 15, and towards the non-filled compartment 34 of the power chamber 13, while in the non-filled compartment 34 of the power chamber 13 a hole 35 is made with a guide sleeve 36 fixed therein, providing a post atelnoe movement transmission mechanism 16.

The hydromechanical device 5 is equipped with a return device 37 of the hydromechanical drive associated with the transmission mechanism 16 and / or the drive membrane and made, for example, in the form of a spring.

The power chamber 13 is equipped with a piston 38, dividing the housing 14 of the power chamber 14 into said compartment 15 with a variable working volume and a compartment 34 which is not filled with it and is filled with a compartment 34 and configured to move in a power chamber depending on a change in pressure, and in a non-filled compartment 34 a power the chamber 13 has a hole 35 with a guide sleeve 36 fixed therein, providing translational movement of the transmission mechanism 16.

Shut-off and / or shut-off and control valves 3 are made with a spindle shut-off element (not shown in the drawings), and the transmission mechanism 16 consists of at least two elements. The first element of the transmission mechanism, the rod 17, is connected through a safety pad 39 to the membrane 33 of the power chamber 13, and the second element 40 is connected to the shut-off element of the shut-off and / or shut-off and control valves 3, preferably through a spindle with the possibility of a rotary movement of the latter. The first and second elements 17 and 40, respectively, of the transmission mechanism 16 are made rectilinear and interconnected movably, for example, by hinge, and in the second element 40, at the junction of it with the first, a hole 41 is made, for example, an elongated slot, inside of which there is a pin 42 connecting both of these elements. The second element 40 of the transmission mechanism 16 is configured to rotate from 0 to 90 degrees from the initial position, while 0 degrees corresponds, for example, to a completely closed valve, and a value of 90 degrees is fully open.

Shut-off and / or shut-off and control valves 3 may be a valve, for example, a ball valve.

The transmission mechanism 16, interacting with the shut-off and / or shut-off and control valves 3, can be made in the form of a lever or crank mechanism, or gear rack 43, or gear 44.

The maximum throughput of the non-return valve 10 of the opening speed controller 9 of said reinforcement 3 is at least two times higher than the maximum throughput of the nozzle 11.

Let us consider the operation of an oil pumping station using an example of an in-plant communication network, primarily, forming the main hydraulic system 1 of an oil pumping station for technological pipelines 2, which connects an external main pipeline to a group of main pressure or booster pumps, and is also regulated with the tank farm or tank of the station. The hydraulic system is mounted with the possibility of implementing the technology of transfer from pump to pump, including switching off reservoirs for the period of operation of this technology, and the mentioned hydromechanical smooth load device 5 is mounted on at least one pressure section of pipeline 2 after the corresponding pump or pump groups.

As the working fluid 6 can be used, for example, an incompressible fluid circulating in the hydraulic system 1 and / or moved through the pipeline 2 of the hydraulic system 1. The opening speed controller 9 of the shut-off and / or shut-off and control valves 3 can be in communication with the power chamber 13 on the other - an intermediate (additional) working fluid 45 or several bodies, liquid and / or gaseous. A gel can be used as a working fluid 6 and / or an intermediate (additional) working fluid 45. When using several working fluids in the area between the opening speed regulator 9 of the aforementioned valves and the power chamber 13, a device or devices of known construction can be used that prevent mixing of the working fluids with each other.

At the beginning of the pumping process, when at least one pressure pump 4 is turned on, preferably with an electric motor 46, in communication with the fluid source on the one hand and with the automatic hydromechanical device 5, on the other hand, the pump 4 is started in two stages : at first - with closed shut-off and / or shut-off and control valves 3 of the hydromechanical device 5, after which the engine runs, preferably, at idle or close to them revolutions, without pumping the volume of the hydraulic medium system, preferably a fluid through the hydraulic system, and pumping it into the opening speed regulator 9 of the aforementioned valve 3, which is connected to the pipe 2 in the area between the pump 4 and the shut-off and control valves 3 of the hydromechanical device 5. Liquid - working fluid 6, passing through the nozzle 11 of the opening speed controller 9 of the shut-off and / or shut-off and control valves 2, enters the power chamber 13. After filling the power chamber 13, the working fluid 6 - the liquid begins to act on the membrane 33, gradually deforming it. The membrane 33, deforming, sets in motion the first element (rod) 17 of the transmission mechanism 16, which moves progressively in proportion to the deformation of the membrane 33, overcoming the force of the return device 37 of the drive, the spring. The translational motion using the first element 17 of the hydromechanical actuator 12 associated with the second element 40 is converted into the movement of the locking element of the shut-off and / or shut-off and control valves 3, aimed at its gradual opening over a certain certain period of time. Before operating the pipeline 2, the nozzle 11 of the opening speed controller 9 of the aforementioned valve 3 is adjusted in such a way as to provide the necessary time interval from the start of the start-up of the pump 4 engine with the closed shut-off and / or shut-off and control valves 3 to its complete opening. After the engine stops and the pressure in the pipeline 2 is reduced, the liquid is forced out of the power chamber 13 through the check valve 10 of the opening speed controller 9 of the said valve 3, which is opened by the pressure of the return device 37 of the hydromechanical actuator 12, by the force generated by the spring of the hydromechanical actuator 12, which exceeds the force created by the return a check valve device 25, wherein the maximum throughput of the check valve 10 is at least two times the maximum pass new ability of the nozzle 11.

Claims (23)

1. An oil pumping station, characterized in that it contains a network of in-plant communications, including those communicated by the pumped product — oil or possibly oil product and gas condensate — forming at least one hydraulic system — process pipelines equipped with a shut-off element and / or shut-off and control valves, pumping equipment, including a group of main pressure pumps, mainly with an electric drive and, preferably, a group of booster pumps s, as well as, preferably, a tank farm equipped at the inlet or at least one tank of the station, a connection to an external supply pipe and / or to a tank fleet, preferably an oil metering unit with filters, a pressure control unit, safety devices, purification devices, equipped with start-up and reception chambers for purification devices and collection of selected contaminants, the receiving-starting unit of these devices and diagnostic tools, an electrical substation, a set of devices and labor cold and / or hot water supply pipelines of the station, industrial and domestic sewage, a boiler room with networks of heat supply pipelines, at least one pressure-filled process pipeline and / or hydraulic pipeline of the water supply or heat supply network of the said oil pumping station is equipped with at least at least one hydromechanical device for smooth loading of the hydraulic system connected to at least one pressure pipe, mainly on the pressure side in the area between the pump or pump group that creates the pressure in the pipeline and the closest shut-off and / or shut-off and control valves connected to the pipeline through the working fluid, mainly through the pumped liquid and mounted with the possibility of automatically prolonged on and off shut-off and / or shut-off and control valves, while the hydromechanical device includes an inlet pipe connected in series with each other, having a housing; shut-off and / or shut-off and control valves and load transfer to a hydraulic system equipped with a non-return valve and a nozzle, and a hydromechanical actuator, including a power chamber with a housing containing at least one compartment with a variable displacement, adjustable refillable with liquid working the body with increasing pressure in the pipeline, and the transmission mechanism, while the connection to the pipeline of the hydromechanical device is double: at the inlet of the inlet pipe it is communicated with the pipeline through to the body, and at the exit, by a kinematically hydromechanical actuator with a locking element of the aforementioned reinforcement, the transmission mechanism is made movable, connected to a power chamber of the piston-rod or membrane-rod type, while the rod, in turn, is movably connected with the formation of a drive with a locking element of the mentioned valves with the possibility of automatic movements of the locking element in the range from full overlap to fully open to the duct and vice versa. 2. The oil pumping station according to claim 1, characterized in that the network of in-plant communications and, primarily, forming the main hydraulic system of the oil pumping station of technological pipelines connecting the external main pipeline with a group of main pressure pumps and, if available, with a group of booster pumps, is also adjustable with a possible tank farm or a station tank, mounted with the possibility of implementing the technology of transfer from pump to pump, including shutdown for a period of boots on this technology tanks when present, and said smooth load hydromechanical device mounted on the discharge pipe section after the corresponding pumping group. 3. The oil pumping station according to claim 1, characterized in that the network of in-plant communications and, primarily, forming the main hydraulic system of the oil pumping station of technological pipelines connecting the external main pipeline with a group of main pressure pumps and, if available, with a group of booster pumps, is mounted with the possibility implementation of the on-site technology for pumping oil or oil products, or gas condensate, for which the oil pumping station is equipped with at least two p tanks, and the piping of tanks and a system for placing shut-off or shut-off and control valves are mounted with the possibility of alternating pumping to one of the mentioned tanks, and at the same time, independent pumping of the mentioned product into the main pipeline from another tank. 4. The oil pumping station according to claim 1, characterized in that the network of in-plant communications and, primarily, forming the main hydraulic system of the oil pumping station of technological pipelines connecting the external main pipeline with a group of main pressure pumps and, if available, with a group of booster pumps, is mounted with the possibility the implementation of pumping technology with the connection of tanks, and the hydraulic system of the plant’s process pipelines is mounted or appropriate By switching the shut-off and / or shut-off and control valves, it is configured to pump oil, oil product or gas condensate entering the station and pump them by main pressure or booster pumps to the subsequent section of the external main pipeline through the same tank of the station. 5. The oil pumping station according to claim 1, characterized in that the hydraulic system of the plant’s process pipelines is mounted or is configured to switch the oil, oil product or gas condensate supplied to the station and pumped through main pressure and / or booster pumps to the subsequent section of the external trunk pipeline, mainly bypassing the tank farm while maintaining the ability to compensate for unbalances by throwing or pumping part of the oil into at least one of the reservoirs of the station. 6. The oil pumping station according to claim 1, characterized in that at least a portion of the main pressure pumps of the station are mounted in series with the possibility of increasing the generated pressure at the outlet of the corresponding group of pumps and in the subsequent section of the external main pipeline, including exceeding the possible technical power to create the pressure of any individual pump from the specified group. 7. The oil pumping station according to claim 1, characterized in that the group of main pressure and / or booster pumps is switched in parallel in the hydraulic system of the station, or in a combined series-parallel circuit through an additional collector. 8. The oil pumping station according to claim 1, characterized in that it includes an engineering laboratory building, a fire station, facilities for setting up and repairing instrumentation, a communication and control station, and a receiving and starting unit for treatment devices and diagnostic tools is mounted and connected to the hydraulic system of the station and the external main pipeline with the possibility of receiving the above funds from the limit switches of the main pipeline section preceding in the product supply direction and starting up into the initial zones subsequent portion of said main pipeline. 9. The oil pumping station according to claim 1, characterized in that it is made head on the main pipeline or on its production site and is equipped with a tank farm included in the hydraulic system of the station by strapping process pipelines made at least partially single-wire or two-wire with the possibility of simultaneously filling two or more tanks or one of them at the same time with the product arriving at the station, and at the same time with the possibility, including simultaneously performing a removable fence through the same and / or other tanks, and at least one of the aforementioned hydromechanical smooth loading device of the hydraulic system is mounted at the outlet of the pressure generating one or a group of pumps. 10. The oil pumping station according to claim 1, characterized in that the aforementioned non-return valve and nozzle are placed in the body of the opening speed controller of said valve, wherein the nozzle and non-return valve are structurally combined. 11. The oil pumping station according to claim 1, characterized in that the check valve of the opening speed regulator of said valve comprises a rod having a passage with outlet openings with a shutter made at one end thereof and a nozzle at the other end, including a screw element that regulates, preferably, a screw element, introduced into the passage channel of the check valve stem with the possibility of at least partially blocking the passage section of the passage channel - the passage hole for its calibration using the nozzle needle, which is equipped with Female screw element, by changing its position relative to the passage channel. 12. The oil pumping station according to claim 1, characterized in that the opening speed controller of said valve is equipped with a return device associated with a check valve and / or nozzle and made, for example, in the form of a spring. 13. The oil pumping station according to claim 11, characterized in that the opening speed controller of said valve is equipped with a return device mounted on the screw element of the nozzle and made, for example, in the form of a spring. 14. The oil pumping station of claim 10, characterized in that the body of the speed controller for opening the shut-off and / or shut-off and control valves contains at least three compartments, in the first compartment there is a check valve with an inlet of the passage channel, in the second compartment there is at least partially a check valve stem and at least one outlet passage of the passage channel made in the rod, in the third compartment there is a screw element of the nozzle and a return device for regulating a torus of opening speed, while the second compartment is connected via a working fluid to the power chamber, and a hole closed by a screw plug is made in the housing of the opening speed controller in the region of the third compartment to provide adjustment of the passage section of the passage channel by means of a screw element. 15. The oil pumping station according to claim 11, characterized in that for changing the position of the nozzle needle relative to the through hole, the nozzle is equipped with a calibration device configured to manually adjust it from the outside of the body of the speed controller for opening the shut-off and / or shut-off and control valves. 16. The oil pumping station according to claim 1, characterized in that the power chamber is equipped with a sealed elastic membrane dividing the power chamber housing into said compartment with a variable working volume and a non-filling compartment, the membrane being made with the possibility of alternating deformation directed depending from pressure, both towards the filled compartment, and towards the non-filled compartment of the power chamber, and in the non-filled compartment of the power chamber a hole with a fixed a bushing that provides translational movement of the gear mechanism. 17. The oil pumping station according to claim 1, characterized in that the hydromechanical device is equipped with a hydromechanical drive return device associated with the transmission mechanism and / or the drive membrane and made, for example, in the form of a spring. 18. The oil pumping station according to claim 1, characterized in that the power chamber is equipped with a piston dividing the power chamber body into said compartment with a variable working volume filled with a working fluid and a compartment that is not filled with it and configured to move in the power chamber depending on the pressure change, moreover, a hole is made in the non-fillable compartment of the power chamber with a guide sleeve fixed therein, which provides translational movement of the transmission mechanism. 19. The oil pumping station according to claim 17, characterized in that the shut-off and / or shut-off and control valves are made with a shut-off element having a spindle, and the transmission mechanism consists of at least two elements, the first element being the rod - transmission mechanism through a safety pad is connected to the membrane of the power chamber, and the second element is connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter. 20. The oil pumping station according to claim 19, characterized in that the first and second elements of the transmission mechanism are made rectilinear and are interconnected movably, for example, articulated, and in the second element at the junction of it with the first there is a hole, inside which there is a pin connecting both the specified element, and the second element of the transmission mechanism is made with the possibility of rotation from 0 to 90 ° from the initial position, while 0 ° corresponds, for example, to completely closed fittings, and a value of 90 ° is completely about open. 21. The oil pumping station according to claim 1, characterized in that the shut-off and / or shut-off and control valves is a crane, for example a ball valve. 22. The oil pumping station according to claim 1, characterized in that the transmission mechanism interacting with the shut-off and / or shut-off and control valves, is made in the form of a lever or crank mechanism, or gear rack. 23. The oil pumping station according to claim 1, characterized in that the maximum throughput of the non-return valve of the speed control valve of the opening of said armature is at least two times the maximum throughput of the nozzle.

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