SU59747A1 - Oil production control device for oil emulsification - Google Patents

Description

Common-veveino when extracting oil along with oil from the well enters the water. If its quantity is small, and it badly defends itself from the “effe,” then this does not cause particular difficulties.

A completely different result is obtained, however, if the WED defends poorly, often for days, and sometimes much longer.

With this, oil is defended from the water in the earth’s enclosure, while the volatile parts of the oil are rubbed and the p itself is absorbed into the ground. To defend it in tanks, such "emulsified oil requires a large capacity of the latter, which increases the cost of production.

This makes it imperative to either have the ability to decompose these emulsions by adding reagents or; by means of electric dehydration, heat, filtration, etc., or find ways to prevent the formation of such emulsified mixtures of oil and water, i.e. , to conduct such a regime of oil production, so that the oil, although extracted with water, but so that their separation Hie

difficulties and did not cause loss of oil.

It can be assumed that in many cases an emulsion is formed at the very end of the path of the oil, i.e., in the vortex, where the oil is closely mixed with water. In this case, it is advisable to conduct production in such a way as to prevent this formation, which occurs mainly due to the close mixing of oil and water at the moment when the jet is sputtered. If the jet has already been emulsified earlier, i.e., at a depth in the pipes, then it is necessary to treat the oil with a reagent in order to destroy the emulsion as soon as possible and not allow it time to stabilize in air.

To control the oil production on the emulsification of oil and serves the proposed device. This device allows one to take a sample of oil from a well and to determine visually the degree of emulsification of oil, as well as to produce a test action (ia) with various reagents.

For this purpose, the device is designed as an oil tank attached to an oil well in a closed tank, fitted with glassed windows throughout its height to observe oil pumped into it and connected to a pipe to deliver compressed air into it it reagents.

In addition, a tank for eroi eo-zdukhom is provided for the tank, in order to keep it open, as well as an annular perforated tube attached to the tube for supplying compressed air.

In the drawing, the device is presented schematically.

The device consists of a reservoir 1, closed OBeipxy and bottom covers. A tube 3 passes into the tank, connected to pump pipe 2, through which production, i.e., oil and water, rises. In cylinder 1 there are two slits, in which two glasses 12 are inserted - on opposite sides of the cylinder, through which it is possible to observe the nature of the liquid entering the cylinder.

Above the cylinder of the mouth of the tank 8 with reagent. Using a tube 11, it is connected to a recess 1, and using branch 10 to a tube 3.

The reservoir 1 and the tank 8 and; there are gauges 15 and 9, with which you can monitor the level of fluids in THEM.

On the tank 8 there is a stopper, screwed into the hole of its upper lid 18 for pouring the required liquid. In addition to branch 10, tube 3 also has branch 19. Thus, the liquid from pump tube 2 can go into both tubes 3 and 19.

The tank 1 also includes a vertical tube 5 for supplying compressed air, reaching the very bottom of tank 1 and passing into an annular perforated tube 14. In addition, tube 20 extends from the tube 5, which connects it to tank 8. Another bone process 6, tube 5 allows it to be connected to the upper space of tank 1.

In addition, another round tube 4 is passed through the cover, through which the tank 1 can be blown, and the liquid is discharged from the latter through the tube 13.

The pipe 11 connecting the tank 8 with the tank 1 is terminated already in the tank itself with a cruciform tube 16 for a more uniform distribution of the fluid admitted into the tank.

On the outer wall of the tank along the windows 12 there are divisions 17, on which it is possible to mono-count the amount of liquid introduced into tank 1.

The operation of the device is as follows.

But the pressure of the manometer, which is usually present at the well, is determined by the pressure in it, and by attaching the tube 3 to the place of the pump tube 2 of the well, from which it is desirable to have a sample of production (oil and water), with the valve of the tube 3 closed air through the tube 5. But the pressure gauge 7 is set when the pressure in the reservoir is 1 ura1V (H is with the pressure in the well. The air is being injected simultaneously MteHHO and into the tank 8 through the tube 20, which is opened for this purpose. Reagent is poured into the tank 8 that can flow m need.

After the air pressure in the tank 1 has reached the pressure value in the well, and practically it is made slightly higher than in the well, the air inlet valve on the tube 5 is closed. Open: tap pipe 3, i.e., the space of reservoir 1 is communicated with the inside of the pump tubes through which the production rises.

In this case, the pressure levels off, and the liquid from the pipe 2 B does not flow from the tank 1, as this is prevented by the air there. In order to fill the tank 1, the valve on the tube 4 is opened, but only so that the injected liquid displaces only a certain amount of air in the tank. In this way, liquids can be accumulated as required. If it is desirable to add liquid Not at one time, but at several, then it is necessary to close the taps each time and again to create a pressure in the system, equal to the pressure in the operating column. The selection of the third, third, etc., portions of the liquid, mark the volumes of the divisions on the scale 17. The total level of the liquid in the tank is monitored by water-measuring glass 15.

If a reagent is to be supplied along the flow path through the pipe 3, the valve 10 is opened, through which the reagent poured into the tank 8 will pass into the pipe 3, as the pressure in the tank 8 is the same as in the whole system. Usually, the tap of tube 10 is left closed. If it is required to pour the reagent into the tank 1 directly, then open the valve on the tube 11.

The nature of the fluid in cylinder I is monitored by the sight glass, point 12.

If it is necessary to mix the liquids in the cylinder, compressed air or gas (in the latter case from the cylinder) is again admitted through the pipe 5, and the air passes through the holes in the annular tube 14 and blows the liquid. Excess air, if operated at elevated pressure, is discharged through valve 4 of the tube.

If mixing is not required, and the pressure in the system is increased, it is pumped in through the same tube 5, but is let in through the tube 6, for which proper edges are opened.

For emptying the tank 1, let in a compressed air through the tube 5 4, opening the tap of the tube 13.

Thus, it is possible to take a sample from the LIQUID flow and make observations on it. If the fluid is stratified well, then there was no emulsification in the borehole, and then it was necessary to only worry, if the fluid was discharged from the well, it could not be pulverized and not emulsified. This is achieved by the well-known npaeyiat K, which is imish; in this case, preventive measures prevent the formation of an emulsion at the exit of the well.

If the observations show that the emulsion has already formed somewhere in the depths, then it is necessary to test it for destruction by adding reagent.

If necessary, test emulsion formation tests can be carried into the tank 1 by the oil through the tube 3 and the water through the hole 19. In this case, the oil going through the tube 3 and the water going through the tube 19 are mixed along the way, in which reagent may be added if required.

Finally, for testing, it gives l; and the well emulsified oil or liquid is mixed only after it enters the atmosphere, it is possible to simultaneously take a sample of this stream directly from the well to tank 1 and through tube 19 separately. In this case, two samples will be obtained - one, selected under conditions of constant pressure in the well, i.e., outside the conditions of overpressure of the jet, spraying, etc., and the other - under normal conditions of oil production.

The subject matter of the invention.

Claims (3)

1. A device for controlling oil production for emulsifying oil, characterized in that in order to be able to sample the desired volume, determine visually the degree of emulsification of oil and affect it with various reagents, it is made in the form of a closed reservoir I attached to the pump tube 2 equipped with oyuns over the entire height and connected to the tube 5 for supplying compressed air and to the tank 8 for reagents. 2. The form of the device, under item 1, characterized in that the tank 1 is equipped with a tube 4 for blowing it with air. 3. In the device on PP. 1-3, use an annular perforated tube 14, installed in a reservoir 1 and attached to the tube 5 for supplying compressed air that mixes the liquid. SiS 2S J 9is 12 ff