RU96609U1 - SYSTEM OF TRANSPORTATION AND INJECTION OF WATER IN PLAST - Google Patents

Abstract

 1. A system for transporting and pumping water into the reservoir, including a water supply source, consisting of treatment facilities and a pump, a main water line with a pressure sensor, a receiving water line with a valve and a discharge water pipe of a cluster pump station with an adjustable valve and a flow meter, a comb unit, high-pressure water pipes, injection wells, characterized in that the discharge line of the pump of the cluster pump station is communicated by an additional line to the main line through the flow regulator, while the regulator stroke operably connected to the flow meter of flow conduit, and an adjustable valve operatively connected to a pressure transducer through a water main programmable controller, wherein the receiving conduit pump group pumping station is further provided with a pressure relief valve. ! 2. The system for transporting and injecting water into the reservoir according to claim 1, characterized in that the pump of the water supply source is equipped with an adjustable drive functionally connected to a pressure sensor of the main conduit.

Description

The proposal relates to the oil industry, in particular, to a system for transporting and pumping water into the reservoir.

A known system for transporting and pumping water into the reservoir (see the manual "Operation of reservoir pressure maintenance systems in the development of oil fields", ed. Zeygman Yu.V., Ufa: Publishing House UGNTU, 2007, p. 179-183), including water supply source, low-pressure main water supply pipe, receiving pump line of the cluster pump station pump, cluster pump station pump, discharge pump line of the cluster pump station pump, comb unit, high-pressure water lines, injection wells. This system is accepted by us as an analogue and the closest analogue.

The known system for transporting and pumping water into the reservoir has the following disadvantages:

- a significant increase in energy costs for the implementation of the technology when regulating water injection by the method of throttling on the discharge pipe of the pump of a cluster pump station;

- the efficiency (efficiency) of the pump of a cluster pumping station decreases significantly when operating in a mode other than optimal, and significantly decreases in a mode other than nominal;

- reduced reliability and durability of the pump cluster pump due to the variability (often changing) of the pump.

The technical objectives of the invention are to reduce the energy cost of pumping water into injection wells by the pump pump due to its operation in optimal / nominal mode, increasing the reliability and durability of the pump pump due to the stability of its operation modes.

The technical problem is solved by a system for transporting and pumping water into the reservoir, which includes a water supply source consisting of treatment facilities and a pump, a main water line with a pressure sensor, a receiving water line with a valve and a discharge water line of a pump of a cluster pump station with an adjustable valve and a flow meter, a comb unit, high-pressure water pipes injection wells.

What is new is that in the system for transporting and pumping water into the reservoir, the flow line of the pump of the cluster pump station is connected by an additional water line to the main water line through a flow regulator, while through a programmable controller, the flow regulator is functionally connected to the flow meter of the discharge flow, and the adjustable valve is functionally connected to the sensor pressure of the main conduit, while the receiving conduit of the pump of the cluster pump station is additionally equipped with a pressure reducing valve.

The drawing shows a process diagram of a system for transporting and pumping water into the reservoir.

It contains a water supply source 1, consisting of treatment facilities 2 and pump 3 of treatment facilities 2, a main water conduit 4 with pressure sensors 5, 6, a receiving conduit 7 with a valve 8 and a discharge conduit 9 of a pump 10 of a cluster pump station 11 with an adjustable valve 12 and a flow meter 13, comb unit 14, high-pressure water conduits 15, 16, 17, injection wells 18, 19, 20, 21, 22, 23. The flow line 9 of the pump 10 of the cluster pump station 11 is connected by an additional water line 24 with a main water line 4 through a flow regulator 25, at the same time, the regulator and 25 is functionally connected to the flow meter 13 of the flow line 9, and the adjustable valve 12 is functionally connected to the pressure sensor 6 of the main water line 4 through a programmable controller 26, while the receiving line 7 of the pump 10 of the cluster pump station 11 is additionally equipped with a pressure reducing valve 27. The pump 3 of the treatment plant 2 equipped with 28 adjustable drive.

At the main water conduit 4, one pressure sensor 5 or 6 is sufficient, however, due to the remoteness of the water supply source 1 and the cluster pumping station 11 (to reduce the costs of telemechanics), the main water conduit 4 is equipped with two pressure sensors 5 and 6. The pressure sensor 5 is geographically owned by water supply 1 and functionally connected with an adjustable actuator 28, and the pressure sensor 6 is geographically owned by a cluster pump station 11 and is functionally connected with an adjustable valve 12, also located in the cluster second pumping station 11.

The scheme works as follows (see drawing). Turn on the pump 3 of the treatment plant 2 and the pump 10 of the cluster pumping station 11. The pump 3 of the treatment plant 2 draws water from the treatment plant 2 and through the main conduit 4 supplies water to the intake conduit 7 with a valve 8 and a pressure reducing valve 27. At the same time, the valve 8 is fully open and the pressure reducing valve 27 keeps (stabilizes) the pressure at the intake of the pump 10 of the cluster pump station 11. The pump 10 of the cluster pump station 11 through the discharge duct 9 through an adjustable valve 12, a flow meter 13, a comb unit 14 and a high nye conduits 15, 16, 17 injects water into the injection wells 18, 19, 20, 21, 22, 23, the flow regulator 25 is closed.

In cases of technological necessity (cyclic injection, scheduled preventive repairs at injection wells, etc.), some of the injection wells 18, 19, 20, 21, 22, 23 are turned off. In this case, the flow controller 25, functionally connected with the flow meter 13 of the flow line 9 through the programmable controller 26, opens, and part of the water is discharged through an additional water line 24 from the flow line 9 of the pump 10 of the cluster pump station 11 through the flow control 25 and enters the main water line 4 and then through the valve 8 and the pressure reducing valve 27 enters the inlet conduit 7 of the pump 10 of the cluster pump station 11. Regulation of water injection at the cluster pump station 11 is carried out by the method of bypassing, When this pump is less energy-intensive treatment plant 2 3 moves (shifts) in the mode characteristic of the left side of the pump characteristics: a high pressure discharge and a decrease in feed (flow) of the water conduit into the receiving bush 7, the pump 10 pumping station 11 by the amount of bypass. At the same time, the operating mode of the pump 10 of the cluster pump station 11 remains unchanged, and the pressure reducing valve 27 keeps (stabilizes) the pressure at the pump 10 of the cluster pump station 11 constant.

In the case when the discharge of water through an additional conduit 24 from the discharge conduit 9 of the pump 10 of the cluster pump station 11 through the flow regulator 25 to the main conduit 4 and then through the valve 8 and the pressure reducing valve 27 to the inlet conduit 7 of the pump 10 of the cluster pump station 11 becomes significant ( for example, more than 15% of the pump capacity; the exact value is determined by the feasibility study for the minimum energy consumption and pump performance 10 and 3), the discharge pressure at the pump 3 treatment plants 2 becomes critical, that is, the operating mode of the pump 3 of the treatment plant 2 becomes uneconomical (or goes beyond the boundaries of the passport operating range). Then the pressure sensor 6, geographically belonging to the cluster pump station 11, which is installed on the main pipeline, like the pressure sensor 5 (geographically belonging to the water supply 1) is hydraulically connected to it, gives a command through the programmable controller 26 to cover the adjustable gate valve 12 (to return pump sewage treatment plants in operating mode, while the degree of cover of the valve is determined on the basis of the minimum total energy consumption for the pumps).

When equipping the pump 3 of the treatment plant 2 with an adjustable drive 28, the pump mode 3 of the treatment plant 2 is maintained in the optimal working area. For example, at the beginning of the discharge of water through an additional water conduit 24, the pressure sensor 5 detects an increase in pressure in the main pipeline and gives the command for an adjustable drive to reduce the flow of the pump 3 of the treatment plant 2.

The regulation of water injection at the cluster pumping station 11 is carried out according to the bypass method, which is energetically more advantageous than throttling, while the pump 10 of the cluster pumping station 11 is operated in constant operation modes. The less energy-intensive pump 3 of the treatment plant 2 in comparison with the pump 10 of the cluster pumping station 11 (for comparison: the average energy consumption of the pump 10 of the cluster pumping station 11 is 500-700 kW, the electricity consumption of the pump 3 of the treatment plant 2 is 50-70 kW) higher pressure mode - the left side of the pump characteristic. Loss of electricity (kW) at the pump 3 of the treatment plant 2 is 8-10 times less than the loss of electricity at the pump 10 of the cluster pump station 11, if the regulation of water injection at the cluster pump station 11 was carried out by the throttling method - by closing the adjustable valve 12.

For more efficient operation of the system for transporting and pumping water into the reservoir, the pump 3 of the treatment plant 2 and, especially, the pump 10 of the cluster pumping station 11, as the most energy-intensive, are selected so that they work in the nominal / optimal mode.

An example of a specific implementation.

There is a system for transporting and pumping water into the reservoir. The water supply 1 is equipped with a central nervous system pump 60-198. The cluster pumping station 11 is equipped with a central nervous system pump 63-1100. There is a task for injection into injection wells in the amount of 1500 m ³ / day. Injection wells 18, 19, 20, 21, 22, 23 have the following characteristics:

- well 18 - injection 200 m ³ / day at an injection pressure of 10.2 MPa, well 19 - injection 100 m ³ / day at an injection pressure of 10.6 MPa, well 20 - injection 310 m ³ / day at an injection pressure of 9.6 MPa, the injection borehole 21 290 m ³ / day at injection pressure of 9.6 MPa, the hole 22 - injecting 300 m ³ / day at injection pressure of 9.6 MPa, the well 23 -zakachka 300 m ³ / day at a pressure of injection 9 6 MPa.

Turn on the central pump 60-198 of the treatment plant 2 and the central pump 63-1100 of the cluster pump station 11. The central pump 60-198 of the treatment plant 2 draws water from the treatment plant 2 and delivers water through the main conduit 4 in the amount of I500 m ³ / cit (63 m ³ / h) with a pressure of 180 meters and a pump efficiency of 67% in the intake pipe 7 with a valve 8 and a pressure reducing valve 27. At the same time, the valve 8 is fully open and the pressure reducing valve 27 keeps (stabilizes) the pressure at the pump inlet constant TsNS 63-100 cluster pumping station 11. Pump TsNS 63-1100 group pumping station 11 to flick water conduit 9 through an adjustable valve 12, flow meter 13, the comb unit 14 and the high pressure conduits 15, 16, 17 injects water into the injection wells 18, 19, 20, 21, 22, 23 in a volume of 1500 m ³ / day (63 m ³ / h) with a pressure of 1100 meters and a pump efficiency of 56%, while the flow control 25 is closed.

In case of technological necessity (cyclic injection), injection well 19 (100 m ³ / day) is shut off. In this case, the flow controller 25, functionally connected with the flow meter 13 of the flow line 9 through the programmable controller 26, opens, and part of the water in the amount of 100 m ³ / day (4.2 m ³ / h) is discharged through an additional water line 24 from the flow line 9 pump TsNS 63-1100 of the cluster pump station 11 through the flow regulator 25 and enters the main conduit 4 and then through the valve 8 and the pressure reducing valve 27 enters the intake pipe 7 of the pump CNS 63-1100 of the cluster pump station 11. Regulation of water injection at the cluster pump station 11 real it is carried out according to the bypass method, while the less energy-intensive central pump 60-198 of the treatment plant 2 switches (shifts) to the mode characteristic of the left part of the pump characteristic: higher discharge pressures and a decrease in the water supply to the main conduit 4 by the amount of bypassing (4.2 m ³ / h). In this case, the less energy-intensive central pump 60-198 of the treatment plant 2 will have the following characteristics: supply - 58.8 m ³ / h, head - 205 m, pump efficiency - 64%. At the same time, the operating mode of the central nervous system pump 63-1100 of the cluster pumping station 11 remains unchanged (flow -63 m ³ / h, head - 1100 m, pump efficiency - 56%), and pressure reducing valve 27 keeps (stabilizes) the pressure value at receiving the central nervous system pump 63-1100 cluster pumping station 11.

The table shows the comparative indicators of the known (closest analogue) and the proposed system for pumping a displacing agent into injection wells.

Table Comparative indicators of the known and proposed object device Indicator Values with known (closest analogue) and proposed systems famous proposed one 2 3 Process water injection, thousand m ³ / year 257.5 257.5 The cost of the equipment used, total, thousand rubles 1910.0 2270.0 including: - pump unit, central nervous system 63-1100 1700.0 1700.0 - pump unit, central nervous system 60-198 210.0 210.0 - water conduit L = 8 m, D = 159x9 mm 22.0 - flow regulator 63.0 - pressure reducing valve 29.0 - pressure sensor, 2 pcs. 26.0 - programmable controller 80.0 - adjustable drive 140.0 The number of overhauls and diagnostics of the central nervous system pump 63-1100, units / year 0.375 0.125 Costs of major repairs and diagnostics of the central nervous system pump 63-1100, thousand rubles 131.1 43.7 Pump overhaul period, h 15,000 22500 The need for capitalization of funds for the purchase of a new central nervous system pump 63-1100 thousand rubles / year 497.3 331.5 Energy costs for water injection, thousand kWh / year 2034.3 1725.3 The cost of energy for water injection, thousand rubles / year 2441.2 2070,4

The table shows that at additional costs for equipment in the proposed scheme (360.0 thousand rubles), they pay off due to energy savings of -370.8 thousand rubles .; energy costs for water injection by 370.8 thousand rubles. (15.2%) lower than the known system; the total annual effect in the proposed scheme in comparison with the known scheme will be 624.0 thousand rubles.

The technical and economic efficiency of the proposed system for transporting water injection into the reservoir is achieved by reducing the energy cost of pumping water into the injection wells by the KNS pump due to its operation in the optimal / nominal mode, by increasing the reliability and durability of the KNS pump due to the stability of its operation modes.

Thus, the use of this invention in the oil industry can reduce the cost of maintenance and repair of water injection systems, the cost per unit (1 m ³ ) of injected water.

Claims (2)

1. A system for transporting and pumping water into the reservoir, including a water supply source, consisting of treatment facilities and a pump, a main water line with a pressure sensor, a receiving water line with a valve and a discharge water pipe of a cluster pump station with an adjustable valve and a flow meter, a comb unit, high-pressure water pipes, injection wells, characterized in that the discharge line of the pump of the cluster pump station is communicated by an additional line to the main line through the flow regulator, while the regulator stroke operably connected to the flow meter of flow conduit, and an adjustable valve operatively connected to a pressure transducer through a water main programmable controller, wherein the receiving conduit pump group pumping station is further provided with a pressure relief valve. 2. The system for transporting and injecting water into the reservoir according to claim 1, characterized in that the pump of the water supply source is equipped with an adjustable drive, functionally connected to the pressure sensor of the main conduit.