HU187092B - Double well structure for separated and controlled heating several particularly two storage layers carried out by burning and steam as well as for producing hot fluids - Google Patents

Abstract

The double cone structure according to the invention, as shown in Fig. 1, is a short tube (12) of the upper connector liner (14a) disposed in the upper storage layer (14a) that extends down to the separating layer (18a), optionally with an ignition probe (15), the eccentric transition (18) of the upper connector liner (14) located in the separating layer (18a), the lower connecting liner (20) and / or the small bottom connector liner (21) connected to the lower storage layer (20a), and the lower storage layer (20a) is provided with a long production tube (17), optionally with an ignition probe (15), having an outer, contact with the eccentric transition (18) provided with a sealing member (19), such as a short production tube (12) and a long the upper part of the production tube (17) extends from one another through the double tube head (10) in a double seal a relay (9), in addition to which one is connected with an air inlet (1) and a lubricant (5). At- ati-o. -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a double well structure for heating, in particular two storage layers, separated and controlled by combustion and steam and for the production of hot fluids.

In oil field cultivation, they switch to secondary and tertiary production processes, when the plant's own energy has been reduced to such an extent that primary cultivation cannot be continued. ' In such cases, thermal processes, often referred to as tertiary petroleum production processes, are often used, in which one type of energy required to produce the oil in the reservoir is produced locally in the storage layer by burning some of the oil or combustible material from outside. Such a process is described, for example, in U.S. Patent No. 1,176,375. Great Britain, and U.S. Patent Nos. 3,400,763 and 3,285,336. U.S. Pat.

In practice, for example, in a so-called ignition well which cuts through the productive layer, the oil is heated to its ignition temperature and the air required for combustion is injected. in this way, a combustion front is formed which is controlled by the injection of air at the desired speed in the container. Meanwhile, hot fluids may also be produced. Steam injection is often used to heat the oil in the tank.

When oil fields are harvested, a well design is used in which the well spans several oil storage layers, whereby oil is extracted simultaneously from several storage layers at different levels. However, none of the wells known in the art are capable of independently igniting each well in a single well and selectively controlling the movement of the combustion front in each layer. In well known well designs, the separation of storage layers at different levels is unsolvable.

It is an object of the present invention to provide a double well structure which is capable of heating, in particular two storage layers, separated and controlled by combustion and steam as well as the production of hot fluids.

It has now been found that the above object is achieved by a double well structure having an upper connection liner in the upper storage layer and extending to the separation layer, a short production tube provided with an ignition probe therein, and an overlapping the latter having a lower connection liner and / or a small lower connection liner in the lower storage layer and a long production tube downstream of the lower storage layer, optionally provided with an ignition probe, the latter being provided with an external eccentric transition, each upper part of the long manifold extends in isolation through a double manifold head into the double main shut-off valve, which is furthermore provided with an air inlet fitting and a lubricant. torrents.

The long production tube may be provided with an expansion piece allowing longitudinal displacements. The expansion insert may consist of an outer ribbed sliding sleeve in the sliding sleeve, a seal, and sliding and striking latches in the operating position with a locking ring.

If desired, the long production tube is provided with a protective tube at the height of the ignition probe released through the short production tube.

Preferably, the sealing member comprises an outer tapered sealing ring and an inner tapered sealing ring which are externally mated to the cylindrical connection portion.

In particular, the double well structure of the present invention is illustrated in FIGS. with the aid of FIG.

Figure 1 is a cross-sectional view of an above-ground and underground portion of an exemplary embodiment of a double well structure.

Figure 2 shows details of the eccentric transition. ---------------------.

Figure 3 shows a sealing member at the eccentric transition.

Figure 4 shows a cylindrical connection portion containing a sealing member at an eccentric transition.

Figure 5 shows the components of the expansion joint.

Figure 6 shows a protective tube placed on the long production pipe.

Figure 1 illustrates the double well structure of the present invention for simplicity of storage layers of two different depths. Between the upper storage layer 14a and the lower storage layer 20a is the separation layer 18a. The upper connecting liner 14 is located in the upper storage layer 14a and extends to the separation layer 18a. The lower storage liner 20a includes the lower connecting liner 20 and / or the small lower connecting liner 21. The eccentric transition 18 is in the separation layer 18a. The long loading tube 17 extends from the double production tube head 10 to the lower storage layer 20a, while the short production tube 12 extends from the double production head 10 to the upper storage layer 14a. Both the long production tube 17 and the short production tube 12 are provided with an ignition probe 15 if desired.

The upper part of the long production tube 17 and the short production tube 12 extends in isolation through the double production head 10 provided with the planting disc 11 into the double main shut-off assembly 9, which is further connected to the air inlet assembly 1 and the lubricator 5 by the double cross-member. The air inlet fittings 1 are provided with an air dispenser la, a pressure gauge 7 and a shut-off fitting 4. The fluid inlet assembly 2, which is connected to the nozzle head 3 and is inserted into the air inlet assembly 1, allows fluid delivery. 5 lubricators fitted with 6 quick release lids. it is possible to insert the ignition probes 15 under pressure and to seal the cable of the ignition probes 15, which is not shown in Figure 1.

The outer portion of the long production tube 17, which is in contact with the eccentric transition 18, is provided with a sealing member 19 which, as shown in FIG. 3, is provided with an outer conical sealing ring 25 and an inner

Contains 187,092 rings. They also fit into the cylindrical connector portion 26 shown in Figure 4.

The material of the inner tapered sealing ring 24 and the outer tapered sealing ring 25 are of high strength with a high yield point. The taper between the two ring surfaces is small (usually 10 - 25 ') but not self-sealing. When the sealing member 19 is screwed into the easy-release nut thread 27, the inner tapered sealing ring 24 and the outer tapered sealing ring 25 slide on the cylindrical portion of the sealing member 19. The inner tapered sealing ring 24 expands outward and the outer tapered sealing ring 25 widens inwardly, so that when tightening the easily soluble nut thread 27, a seal is formed between the long production tube 17 and the eccentric transition 18. This provides a hermetic seal of the lower storage layer 20a from the upper storage layer 14a.

The long production tube 17 is provided with an expansion piece 13 which, by its design, allows longitudinal displacements, generally within a range of 50 cm. These displacements may be due, for example, to thermal expansion or may occur during assembly, such as by screwing the sealing member 19.

As shown in Fig. 5, the expansion insert 13 comprises an outer ribbed sliding sleeve 32 with a stop belt 30, a gasket 29 and a sliding and stopping lock 33 in the operating position with the locking ring 31. The sliding sleeve 32 may move in the sliding sleeve 281. The locking ring 31 is preferably secured by welding.

The expansion member 13 bears the longitudinal forces of the long production tube 17, providing pressure and transmitting the torque required for screwing in.

The ignition probe 15 can pass through the long production pipe 17 and the short production pipe 12 and is suspended by a cable. For ignition, either at the lower end of the long production tube 17 or the short production tube 12, or deeper. In the latter case, when the upper storage layer 14a is ignited by the ignition probe 15 discharged from the short production tube 12, the adjacent portion of the long production tube 17 may be adversely affected. To prevent this, the long production tube 17 may be provided with a protective tube 16 at the height of the ignition probe 15 discharged through the short production tube 12, as shown in Figure 6. The protective tube 16 can be pulled onto the portion of the long production tube 17 to be protected and secured with the screws. The required thermal insulating effect is provided by the air layer between the protective tube 16 and the long production tube 17.

In the case where the ignition probe 15 is located at the ends of the short production tube 12 and the long production tube 17, the end of the tube is preferably provided with a heat-reflecting and insulating liner.

The double well structure according to the invention is cemented by the upper connecting liner 14 and the lower connecting liner 20. This cementation is performed after the exact location of the upper storage layer 14a and the lower storage layer 20a has been determined so that the eccentric transition 18 enters the separating layer 18a. The top connection liner 14 is cemented to the surface. The upper storage layer 14a and the lower storage layer 20a are opened for production by perforating the upper connection liner 14 and the lower connecting liner 20 with the cement layer to a sufficient depth.

During the cementing and perforation process, it is necessary to protect the easily soluble nut thread 27 and the cylindrical connection portion 26 of the eccentric transition 18 shown in Figure 4. This protection is provided by the plastic seal 23 and by screwing the protective sleeve 22 as shown in FIG.

With the double main shut-off valve 7, the short production pipe 12 and the long production pipe 17 can be opened and closed independently by a complete section.

Compressed air can be introduced into the short production pipe 12 and the long production pipe 17 via the air supply device la via the air inlet assembly 1 with a shut-off valve 4 and a pressure gauge 7. If desired, a liquid may be added to the air through the nozzle 3. The jet of the radially outlet nozzles is captured by the jet of liquid air.

In the case of a wet well firing of a double well structure according to the invention, the water / air ratio can be controlled individually for each layer, and for high thickness layers the correct choice of water / air ratio for each layer can reduce gravity segregation. with the oil yield factor.

Although in the exemplary embodiment of the apparatus of the invention described above, separate storage and controlled combustion heating of the two storage layers is referred to, the device of the invention can, of course, be used for more than two storage layers.

The double well structure of the present invention allows individual storage layers to be lit individually and, without overheating the well, to equalize the movement of the air by controlling the injection of air or, in the case of wet combustion, the water / air ratio per layer. Thus, the combustion operation of each layer can be individually controlled.

Claims (6)

A double well structure for heating, in particular two storage layers, separated and controlled for combustion and steam and for producing hot fluids, characterized in that the upper connection layer (14) in the upper storage layer (14a) and extending to the separation layer (18a) a short production tube (12) located, optionally with an ignition probe (15), an eccentric transition (18) under the upper connecting liner (14) in the separating layer (18a), the lower connecting liner in the lower storage layer (20a) (20) and / or small lower connecting lining tube (21) and long production tube reaching down to lower storage layer (20a), optionally provided with ignition probe (15) 3 187 092 (17) having an outer portion in contact with the eccentric transition (18) provided with a sealing member (19), the upper portion of both the short production tube (12) and the upper portion of the long production tube (17) extending in isolation. via a production pipe head (10) to a double main shut-off valve (9), which is further connected to an air inlet assembly (1) and a lubricator (5). Second double well structures according to claim 1, embodiment, wherein the long-mounted spatial expansion spacer allowing melöcső ¹⁰ (17) longitudinal displacement (13). 3. double well structures according to claim 2 embodiment, wherein the expansion insert (13) of the sliding sleeve (28) eihelyezke- ¹⁵ DO, külsőbordás csúszóhüvelyből with abutment shoulder (30) (32) with a seal (29), and The locking ring (31) comprises sliding and stopping locks (33) in the operating position. A double well construction according to claim 1, characterized in that the long production tube (17) is provided with a protective tube (16) at the height of the ignition probe (15) which is discharged through the short production tube (12). 5. Double well construction according to claim 1, characterized in that the sealing element (19) comprises an outer tapered sealing ring (25) and an inner tapered sealing ring (24) which are fitted outside the cylindrical connection portion (26). 6 pieces of figure element Index i7 long production tube 18 eccentric transition 18a separating layer 1 air inlet fitting 19 seal la air supply 30 20 lower connecting lining tube 2 fluid inlet assembly 20a bottom storage layer 3 nozzle 21 small lower connecting lining tube 4 shut-off valve 22 protective sleeve 5 lubrikátor 23 plastic seal 6 quick release cover 35 24 inner tapered sealing ring 7 pressure gauge 25 outer tapered sealing ring 8 double cross section 26 cylindrical connection part 9 double main shut-off valve 27 easily soluble nut thread 10 double production tube 28 sliding sleeve 11 planting disc 40 29 seal 12 short production tube 30 colliding shoulder 13 expansion joint 31 Retaining Ring 14 upper connecting liner 32 outer sleeve sliding sleeve 14a upper storage layer 33 sliding and stop latch 15 spark probe 45 16 conduit Published by the National Office for Inventions