UA109492U - METHOD OF NATURAL GAS PRODUCTION - Google Patents

Abstract

A method of extracting natural gas in the high seas involves collecting gas from gas flares over gaseous portions of the seabed by means of a domed gas collector located in the marine environment, thereby transferring gas from the reservoir to a buffer reservoir and compressing its gas. and signaling to the vessel-collector at a predetermined filling of the storage tank and the shipment of its contents to the vessel-collector, using the dome as a storage tank Positive buoyancy tank having an open buoyancy which is open from below and connected from above with a buoyancy outlet pipeline, the reservoir being placed in the water column above the bottom, pre-determining the spatial location of at least two gas flares and placing above each domed gas collector. Each of the gas collectors produces the resulting gas from the rash from the seabed to a separate pressure regulator, while adjusting the output gas pressure from the gas collectors is carried out to a predetermined level and transferred to the storage tank for accumulation.

Description

The useful model belongs to the methods of extracting natural gas in the open sea, namely the gas that freely comes out of the areas of gas release from the seabed.

A known method of extracting natural gas in the open sea, which consists in collecting it from bottom flares above gas areas of the seabed with the help of a dome-shaped gas collector installed on the surface of the area of the seabed that emits natural gas, and transporting it through a pipeline to the surface of the sea |11.

The disadvantage of the method is ensuring gas production from only one source of gas release from the seabed, while in many cases there is a need for simultaneous gas extraction from several areas of gas seepage on the seabed (21. This leads to a decrease in gas extraction productivity.

There is also a known method of natural gas production in the open sea, which includes collecting gas from bottom flares above the gas extraction areas of the seabed with the help of a dome-shaped gas collector installed on the surface of the gas extraction area and transporting gas to the surface of the sea, while collecting gas from deep-sea sources before transportation gas is supplied to gas holders installed above the gas-separating area of the bottom and connected to the gas reservoir, and gas transportation to the surface is carried out by separating the gas holders from the gas reservoir and their subsequent floating. Also, in the method, before transportation, the gas is liquefied by compressing it with a compressor |Z).

The disadvantage of the given method is its low functionality, since the method is designed to collect gas from a gas extraction site above a gas field, the location of which is known, in addition, such deposits have a limited number of gas extraction sites, as a rule, these are underwater emergency wells. At the same time, at sea, a significant amount of gas is released from the seabed due to seepage of gas from the formed cracks in the earth's crust, mud volcanoes, and bottom gas seepages of the "vulture" type (2). For such sources of natural gas, the technical solution according to the given method cannot ensure high efficiency of gas collection from seepage, because the exact location of such an object is not known, and even more so, the parameters of the mounds are not known, which does not allow to completely capture the seepage gas from the seabed and control the intensity of gas seepage from the seabed.

З The most closely related technical solution adopted as a prototype is the method of gas extraction in the open sea, which freely exits from areas of gas release from the seabed |41|.

In the method, gas is collected from gas flares above gas-releasing areas of the seabed using a dome-shaped gas collector installed on the surface of the seabed.

The obtained gas is transferred from the gas collector to the storage tank, from which, when it is filled, the accumulated gas is discharged, and in order to reduce the gas volume in the process of its collection, it is compacted. After that, gas is supplied to the collecting vessel at the specified filling of the storage tank and its contents are shipped to the collecting vessel. At the same time, a dome-shaped container with positive buoyancy is used as an accumulation tank, which is open from the bottom and connected to the supply pipeline from above, which is also provided with buoyancy. At the same time, the storage tank is placed in the water column above the bottom so that its top is located at a depth where the water pressure exceeds the dissociation pressure of the natural gas hydrate at a temperature corresponding to the annual maximum water temperature, while the location of two gas flares in the extreme case is pre-detected and a dome-shaped gas collector is placed above each of them, and each of them is connected by pipelines to the cavity of the storage tank. In addition, at least the supply pipeline and pipelines of gas collectors are provided with means of electric heating

IM.

The disadvantage of the given method is the complexity of its technical implementation due to the use of a large number of gas reservoirs and the use of various technological processes to change the state of the gas obtained from the seabed, in particular by means of compacting the volume of gas, as well as its transformation into gas hydrate form and back to the usual state . In addition, in this method, the loss of gas from low-pressure bursts when it accumulates in the storage tank is possible.

The useful model is based on the task of increasing the efficiency of gas collection, which is released by blowouts from the seabed, due to the collection of gas not only from powerful blowouts, but also from low-power blowouts.

The technical result of the useful model is the creation of a highly efficient method of extracting natural gas in the open sea. The use in the method of means of equalizing the pressure of gases supplied to the storage tank from both powerful and low-power surges allows you to avoid gas losses from low-power surges that have a low output pressure.

The set task of a useful model is solved by the fact that in the method of natural gas extraction in the open sea, which includes collecting gas from gas flares above the gas-emitting areas of the seabed with the help of a dome-shaped gas collector located in the marine environment, while ensuring the transfer of gas from the gas reservoir to the buffer storage capacity and carry out the discharge of gas and compaction of its volume and the transmission of a signal to the collector vessel when the storage tank is filled and its contents are shipped to the collector vessel, while a dome-shaped container with positive buoyancy, which is open from below, is used as the storage container. and from above it is connected to the outlet pipeline, which is provided with buoyancy, while the storage tank is placed in the water column above the bottom, having previously determined the spatial location of at least two gas flares, and a dome-shaped gas collector is placed above each of them, while according to a useful model, each of the gas collectors is sends the gas received from the seep from the seabed to a separate pressure regulator and adjusts the output pressure of the gas from the gas reservoirs to the specified level and transfers it through the pipelines to the storage tank for storage.

Also, in the method, gas collectors are placed above gas deposits directly on the seabed and/or at a given acceptable distance from the seabed. In addition, in the method, the collection of seep gas from the seabed is carried out while ensuring its industrial suitability.

Compared to the closest analogue (|41), proposed according to the useful model, the method of natural gas extraction in the open sea differs in the following features: - each of the gas reservoirs releases the obtained gas from the seep from the seabed to a separate pressure regulator; - adjust the output pressure of gas from the gas collectors to the specified level and transfer it through the pipelines to the storage tank for storage; - placement of gas reservoirs above gas deposits is carried out directly on the seabed and/or at a given acceptable distance from the seabed; - perform collection of seep gas from the seabed while ensuring its industrial suitability.

These features are essential and ensure the achievement of the set task of a useful model.

Due to the fact that the method uses regulation (reduction) of the output gas pressure from

The loss of gases from low-pressure wells, i.e., low-power gas wells, is excluded from the gas collectors, and this allows for the simultaneous collection of gas from a group of gas wells of different capacities operating on the seabed site in the area of gas extraction. In this way, the efficiency of natural gas extraction in marine conditions increases. This is also facilitated by the regulation of the distance at which the gas reservoir must be located from the seabed, as it also guarantees the possibility of a rational selection of the gas reservoir output pressure, which allows for higher gas extraction productivity in the field. In addition, the proposed method provides an opportunity to quickly assess the industrial suitability of the seabed area for industrial gas production and not to waste money in case of low production productivity.

The technical essence of the useful model is explained by the drawing. The drawing schematically shows a complex for the extraction of gas in the open sea. The following designations are adopted on the drawing: 1 - seabed, 2 - gas reservoir, Z - storage tank, 4 - flexible pipeline, 5 - gas collecting vessel (tanker), 6 - auxiliary vessel with crane winch, 7 - crane with winch, 8 - gas collector pipeline, 9 - gas reducer, 10 - sling, 11 - buoyancy, 12 - cable of the power supply and control system of the complex, 13 - anchor load, 14 - gas jet.

Gas reservoir 2 and storage tank C are structurally similar and differ in size (the volume of the cavities of the first is about a hundred cubic meters, while the second object has about 5-10 thousand cubic meters. They are made in the form of soft shells made of strong synthetic materials, enclosed in a mesh frame made of synthetic ropes, to the lower points of which anchor loads 13 are attached. Gas reservoirs 2 can also be made in the form of a rigid frame, which is mounted in place or "self-opening" (for example, using shape memory alloys), which is provided soft casing and anchor loads 13. The upper sections of the gas reservoirs 2 are equipped with gas reducers 9, which regulate the pressure of the gas released at the outlet to a given level (see gas jet 14), i.e., the pressure of the same level is released at the outlet of the gas reducers 9 regardless of gas collector 2 operating at the entrance. This allows storage tank C to receive gas from gas collectors 2, regardless of the fact that they will different in pressure level at the entrance of gas collectors 2. From the outputs of gas reducers 9, gas is supplied through pipelines 8, which can be of both flexible and rigid construction. The outlet ends of the pipelines bo 8 are held in the lower plane of the storage tank Z by floats 11. The gas obtained from the gas tanks 2 is collected in the upper part of the dome of the storage tank Z and when it is filled, it is transmitted according to the command coming through the cable 12 from the power supply and control system of the auxiliary ship complex 6 through a flexible pipeline 4 to a gas gathering vessel 5 (tanker). The flexible pipeline 4 is held in the working position by floats 11 and a crane with a winch 7 of the auxiliary vessel 6.

As a source of gas, bottom gas flares are used, namely gas flues. These gas seeps are detected by seismoacoustic profiling and/or echo sounding, and/or side-view locator surveying, and/or gas-geochemical studies.

Next, two or more gas reservoirs 2 are lowered to the seabed 1, covering the "sources" of the gas flares with them, after which the storage tank 3 is lowered into the water area, melting it in different directions, due to the appropriate distribution of anchor loads 13 on the area of the seabed, at least four , and in height due to the occurrence of the Archimedean force, which manifests itself when the storage tank C is immersed in water, since it will be directed upwards, and the "work" of gravity, which is applied downward from the anchor loads. At the same time, the storage tank C is placed in the water column above the seabed 1, so that the distances to the gas reservoirs are minimal. Next, the gas collectors 2 are connected to the gas reducers 9 and the reducers are adjusted in such a way that gas is released from them with an acceptable level of pressure from both powerful and low-power gas jets. After that, with the help of pipelines 8, the outputs of the gas reducers 9 are connected to the cavity of the storage tank 3.

For this, the floats 11, which are fixed at the ends of the pipelines 8 of the gas collectors 2, are positioned under the storage tank and fixed in this position with the appropriate anchor loads 13 or introduced from below into the cavity of the storage tank З by an amount that excludes their displacement by bottom currents. In the initial position, the flexible pipeline 4 is closed by the shut-off valve according to the command that was transmitted by the power supply and control system of the complex through the cable 12 from the auxiliary vessel 6 with the crane winch 7. With the help of buoyancy 11, the crane winch 7, the storage tank C is flooded at a depth that excludes the impact surface disturbance and other adverse factors.

Next, gas is collected with the help of dome-shaped gas collectors 2, catching gas flares with them. The trapped gas floats through pipelines 8 into the cavity of the storage tank 3,

By gathering in its upper part. When the storage tank is about to be filled with gas, the flexible pipeline 4 is connected to the receiving pipeline of the collecting vessel 5 and the gas is liquefied and its accumulation is ensured. At the end of the process of gas shipment, the shut-off valves are closed by the team from the auxiliary vessel b through cable 12 of the power supply and control system of the complex. Then everything is repeated at the command of the operator.

The method provides not only the placement of gas reservoirs 2 above the gas seeps directly on the seabed, but also at an acceptable distance from the seabed. This situation occurs when the diameter of the seep is much larger than the dimensions of the gas reservoir 2, and also when the bottom soil under the seep has irregularities or low strength. In this case, it is necessary to use means of buoyancy in order to raise the gas reservoir 2 from the seabed and collect gas at this position of the gas reservoir.

Also, the method has another important function, which is the detection of the insufficient power of the gas source of gas for normal gas collection due to its low pressure, this is detected with the help of a gas reducer.

The proposed method of natural gas extraction allows to improve the efficiency of gas extraction due to the reduction of losses in comparison with the prototype (4), therefore the task set in the useful model is fulfilled.

Sources of information: 1. Author's certificate of the USSR 501498908, IPC E21B 43/00, published on August 7, 1989. 2. Shnyukov E.F., Kobolev V.P., Pasinkov A.A. Gas volcanism of the Black Sea. K.: Lotus, 2013. - 394 p. 3. Patent of the Russian Federation VO2078199 C1, IPC E21B 43/01, published on April 27, 1997. 4. Patent of the Russian Federation VI 2393337 C1, IPC E218B 43/01, published on June 27, 2010 (prototype).

Claims (3)

USEFUL MODEL FORMULA 1. The method of natural gas production in the open sea, which includes collecting gas from gas flares above gas-releasing areas of the seabed with the help of a dome-shaped gas reservoir located in the marine environment, while ensuring the transfer of gas from the gas reservoir to the buffer storage tank and carrying out gas discharge and compaction of its volume and sending a signal to the collecting vessel when the storage tank is filled and its contents are shipped to the collecting vessel, while a dome-shaped container with positive buoyancy is used as the storage tank, which is open from below and connected to the outlet pipeline from above, which is provided with buoyancy, while the storage tank is placed in the water column above the bottom, having previously determined the spatial location of at least two gas flares, and a dome-shaped gas collector is placed above each of them, which is distinguished by the fact that each of the gas collectors emits the gas obtained from the seep from the seabed on separate regulator pressure, while adjusting the output pressure of gas from the gas reservoirs is carried out to the specified level and transferred to the storage tank for storage. 2. The method according to claim 1, which is distinguished by the fact that the placement of gas reservoirs above gas seeps is carried out directly on the seabed and/or at a given acceptable distance from the seabed. 3. The method according to any one of claims 1, 2, which differs in that the collection of seep gas from the seabed is performed while ensuring its industrial suitability.