UA117631U - METHOD OF GAS PRODUCTION FROM BATTLE GAS - Google Patents

Abstract

A method of extracting gas from bottom gas hydrates involves erosion of bottom gas hydrates, covering the surface of a gas hydrate deposit with a gas-collecting structure, supplying a coolant under it, forming a thermal field, decomposing a gas-hydrate deposit, and removing formed gas from the roof of a gas-collecting structure. The bottom sediments are washed by the jets of the coolant, which is fed by flexible perforated pipes, which are loaded to the bottom and connected to the laid down bottom of the heat pipe, the gas-collecting structure is performed as a shielding elastic shell and fixed to the surface of the gas-hydrated deposit by anchors. The formed gas is diverted by flexible pipes from under the shielding to the gas pipeline laid at the bottom and directed to the coastal strip or offshore platform.

Description

The claimed utility model relates to the development of minerals, in particular to the extraction of methane from near-surface accumulations of solid gas hydrates in bottom sediments of lakes, seas and oceans.

There is a known method of extracting methane gas from marine gas hydrate deposits, the main principle of which is to supply heat to the productive zone of the gas hydrate deposit, which causes its dissociation due to the disruption of the phase equilibrium in the direction of decomposition of the gas hydrate into gas and water. The method is carried out by drilling wells from offshore platforms or ships into the gas-hydrate layer, followed by injection of the coolant. Methane, released in the local area of the coolant, is pumped along with water through pipes to a marine platform (vessel), where the gas is separated and stored.

The disadvantage of the method is the costs associated with offshore drilling of wells, in particular the need for the operation of a marine platform, complex drilling equipment, well equipment, increased energy consumption of development. At the same time, the volumes of the obtained gas cannot be significant, since the dissociation process takes place only in the local zone of the formation, where the coolant is supplied, and the rate of methane release is slow. Part of the released methane breaks into the water space and is lost |11.

There is a known method in which a dome-shaped trap open from the bottom of gas hydrate decomposition products is lowered on a cable from the side of a watercraft to the seabed with gas hydrate deposits. The sharp edge of the catcher sinks into the bottom soil under the influence of its own weight, ensuring sealing. An electric pump installed on the body of the catcher pumps out seawater from under the catcher, changing the hydrostatic pressure and phase equilibrium of the gas hydrate, which leads to the release of gas, which is pumped out of the dome of the catcher.

The disadvantage of the method is the zone of dissociative influence on the gas hydrate deposit, which is limited by the dimensions of the dome-shaped trap, which significantly reduces the volume of possible gas production. In addition, the constant need for the operation of the floating vehicle, the high material consumption of the trap design and the complexity of the equipment negatively affect the cost of the extracted gas (21.

The closest in terms of technical essence is the method of extracting gas from gas hydrates of bottom sediments, which involves lowering to the seabed from the side of a marine platform or a well of a gas collection structure in the form of a bell, to the closed end of which supply pipes are connected

From the coolant (natural water) and pumping out the formed water-gas mixture. Erosion of bottom sediments is carried out by a system of pipes, which are laid along the inner side of the bell to its edge.

The disadvantage of the method is the localization of the zone of influence of the coolant on the surface of the gas hydrate deposit, due to the small size of the bell, which significantly limits the volume of gas production.

Taking into account the significant costs of the constant operation of a marine platform or vessel, the cost of the obtained water-gas mixture will be significant. In addition, the problem of accumulating the obtained gas on the vessel and its effective transportation to the consumer |ZI has not been fully resolved.

The useful model is based on the task of improving the method of gas extraction from bottom gas hydrates by simultaneous dissociation of large surface areas of the gas hydrate deposit and capture of the released methane under an extended gas collection screen, which will increase production volumes.

The set technical problem is solved by the fact that the method of extracting gas from bottom gas hydrates includes washing out bottom gas hydrates, covering the surface area of the gas hydrate deposit with a gas collection structure, feeding a heat carrier under it, forming a thermal field, decomposing the gas hydrate deposit and removing the formed gas from the roof of the gas collection structure, according to the useful according to the model, bottom sediments are eroded by jets of the heat carrier, which is fed through flexible perforated pipes that are attached to the bottom and connected to the heat pipe laid along the bottom, the gas collection structure is performed as a shielding elastic shell and fixed on the surface of the gas hydrate deposit with anchors placed along the contour of the shell, and the formed gas are diverted by flexible pipes from under the shielding shell to the gas pipeline laid along the bottom and directed to the coastal strip or offshore platform.

What is also new is that elastic casings are placed sequentially, forming a long system of shielding the surface of the gas hydrate deposit, along which heating and gas pipelines are laid along the bottom and connected by flexible pipes to each gas collection casing.

Due to the fact that bottom sediments are washed away by jets of heat carrier, which is supplied through flexible perforated pipes attached to the bottom and connected to the heat pipe laid along the bottom, it ensures the simultaneous dissociation of large surface areas of the gas hydrate deposit, since large volumes of heat carrier can be supplied through a stationary heat pipe under significant pressure , which are distributed by flexible perforated pipes over a large area of bottom sediments.

The fact that the gas collection structure is performed as a shielding elastic shell, which is fixed on the surface of the gas-hydrate deposit with anchors placed along the contour of the shell, ensures the accumulation of released gas under the elastic shell in the form of powerful gas lenses and further removal of pure gas, not a water-gas mixture. At the same time, the shell acts as a limiter for the spread of the coolant (warm water), which is supplied to the bottom through perforated pipes and which displaces natural cold water from under the shell in the spaces between the anchors, while due to the formation of the necessary thermal field, the return of gas into gas hydrate is excluded.

Thanks to the fact that elastic gas-collecting shells are placed sequentially, forming a long system of shielding the surface of the gas-hydrate deposit, simultaneous collection of large volumes of released gas is ensured on a significant area of the gas-hydrate deposit.

The fact that the formed gas is diverted by flexible pipes from under the gas-collecting shell to the gas pipeline laid along the bottom, which is directed to the coastal strip or marine platform, allows to increase the efficiency of gas removal and minimizes the costs of its transportation to the consumer.

The essence of the useful model is explained by the drawing: where in fig. 1 shows a diagram of the implementation of the method, which includes a gas hydrate layer 1 located at the bottom of the reservoir, the surface of which 2 is eroded by the heat carrier, a heat pipe C for supplying the heat carrier and a gas pipe 4 for gas removal, flexible perforated pipes 5 connected to the heat pipe, equipped with loads 6, a gas collecting elastic shell 7, fixed on the surface of the gas hydrate deposit with anchors 8, which has a hole with a coupling 9 in the central part and is connected by a flexible gas pipeline 10 to the gas pipeline. The gas hydrate washout zone 11 and the released gas lenses 12 are located under the flexible shell.

Fig. 2 is the same, top view.

The method is carried out as follows.

From the coastal strip or marine platform (not shown) along the productive section of the bottom gas-hydrate deposit 1, the surface 2 of which is eroded, stationary

From pipelines with a closed end - heat pipe C for supplying the coolant (which is covered with heat-insulating material) and - gas pipe 4 for gas removal. Flexible perforated pipes 5 are connected to the heat pipe C and placed perpendicular to the heat pipe on the surface 2 of the gas-hydrate deposit 1, pressing them to the bottom with loads 6. Elastic shells 7 are delivered to the place of development of the gas-hydrate deposit 1 by floating means, which are equipped along the contour with anchors 8 (for example, steel bars in the shell pockets) and successively sink to the bottom next to each other, covering flexible perforated pipes 5 with them. In the middle of the gas collection shell there is a hole with a coupling 9 (it can be equipped with a gas-permeable and water-tight filter), to which a flexible gas pipeline is connected 10, connecting to the stationary gas pipeline 4. Watercraft, an underwater module, and divers (not shown) may be involved during the transportation and installation of the equipment. After the installation of the equipment, a heat carrier (for example, hot water from a heating plant, or coastal sea water, the temperature of which can be 15-20"C higher than the temperature of the bottom gas hydrate) is fed into the heat pipe C.

The heat carrier under the specified pressure enters the flexible perforated pipes 5, erodes the surface of the gas-hydrate deposit, displaces natural cold water from under the shell, forming a distributed thermal field. In the gas hydrate washout zone 11, the dissociation process takes place, and the released gas accumulates in the roof of the gas collection shell in the form of powerful lenses 12, from which they are led by a flexible gas pipeline 10 to a stationary bottom gas pipeline 4 and transported to the consumer.

Thus, the claimed method solves the problem of increasing the volume of gas production from bottom gas hydrates by simultaneously dissociating large areas of the surface of the gas hydrate deposit and capturing the released methane under a spacious gas collection screen. In addition, thanks to the claimed method, the cost of the obtained gas and its transportation to the consumer is reduced.

Sources of information: 1. Bondarenko V.I. Gas hydrates. Hydrate formation and basics of development of gas hydrates /

V.I. Bondarenko, O.Yu. Vityaz, M.L. Zotsenko et al. - Dnipropetrovsk: Litograf, 2015. - 219 p. 2. KO 2402674. A method of extracting gases and fresh water from underwater gas hydrates by reducing hydrostatic pressure. IPC: E21B 43/01, 43/36. Publ. 27.10.2010. 3. KO 2412337. A method of extracting methane from bottom deposits of solid gas hydrates. IPC:

E218 43/01. Publ. 10.11.2013. (510)

Claims (2)

USEFUL MODEL FORMULA 1. The method of gas extraction from bottom gas hydrates, which includes washing out bottom gas hydrates, covering the surface area of the gas hydrate deposit with a gas collection structure, feeding a heat carrier under it, forming a thermal field, decomposing the gas hydrate deposit and removing the formed gas from the roof of the gas collection structure, which is distinguished by the fact that it is washed out bottom deposits are carried out by jets of the heat carrier, which is fed through flexible perforated pipes that are loaded to the bottom and connected to the heat pipe laid along the bottom, the gas collection structure is made as a shielding elastic shell and fixed on the surface of the gas hydrate deposit with anchors placed along the contour of the shell, and the formed gas is removed by flexible pipes from under the shielding shell to the gas pipeline laid on the bottom and directed to the coastal strip or offshore platform. 2. The method of extracting gas from bottom gas hydrates according to claim 1, which is characterized by the fact that elastic shells are placed sequentially, forming a long system of shielding the surface of the gas hydrate deposit, along which heat and gas pipelines are laid along the bottom and connect them with flexible pipes to each gas collection shell. : Rfuzh ki lo iVu! Her work is: ION mah age SHHI o AN pok Veloethical nnnnnn nnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnn of her "horn. shi m ni ak Y SHO: ak vky she Ve Kona zani Mam zamah zisaam SYN sweat ЖEK SV ZK SV PI VC NYA pi ee sna us pt s t sho a a i NI what : vne Za ZEAN M i t M rosy n u um In PV t E ZVO nyny s a i NN SK oker i a on oo a u wk S: Shottnya ANNU U YADE too I ZVI I i u i ron i en ty LELEZHEKM t, slot zinide ZESCHU ECO Fi 2