UA19698U - Installation for natural gas extraction from gas-saturated underground water - Google Patents

Abstract

Installation for natural gas extraction from gas-saturated underground water is intended for installation on well, it has main drive string with the lower end intended for placement in water-bearing bed, at that the main drive string had section of perforation intended for placing in the place of rock salt deposition, lift string installed in the main drive string, its lower end is intended for placement at the upper boundary of water-bearing level, circulation packer is installed in inter-pipe space, the upper end of the main drive string is equipped with head and preventer, and the installation is provided with pump station intended for fresh water or water with low mineralization supply to inter-pipe space.

Description

Description of the invention

The proposed utility model relates to mining, namely, to a plant for extracting 2 natural gases from gas-saturated groundwater.

It is known that more than half of the carbon on Earth is in the form of compounds, mainly as solid gas hydrates and as gas-saturated groundwater, in particular, in the form of methane hydrate (E.O. 5ioap, Sia(Ngaye

Nuagaiez oi Maiiga| Sazev, M.U., Magseyi! OeckKeg, 1990; T.V. Rodionova, D.V. Soldatov, Yu.A. Dyadin, Zh. Chemistry in the interests of sustainable development, 6 (1998) 51-74; G.D. Ginzburg, V.A. Soloviev, Submarine gas hydrate, 70 St. Petersburg: ed. State University of Oceanology, 1994). Huge reserves of natural gases, the amount of which is compared to the amount of oxygen in the Earth's atmosphere, are contained in the form of carbon compounds in the bottom areas of deep water bodies at depths from several to 300 - 500 meters from the bottom. Most of them are solid substances, which in terms of structure are gas hydrates - crystalline compounds of a nonstoichiometric composition of the type СНапНоС (where n - 6 - 8), which are formed in thermobaric conditions, for example, 2.17MPa and 268K in the methane-ice system, 2 ,57MPa and 273K or 72 23MPa and 293K in the methane-water system, etc. At the same time, an increase in temperature leads to an increase in pressure, at which the decomposition of gas hydrate begins, and vice versa. In addition to methane, such gas hydrates form ethane, propane, CO, etc., noble gases, etc., but the main component is methane itself. When such hydrates come into contact with groundwater, they emit gases that dissolve in water.

The closest to the proposed one in terms of technical essence is the installation for extracting natural gases from gas-saturated groundwater, which is intended for its installation on a well, and contains the main casing string, the lower end of which is intended to be located in the aquifer |Kaplan E.M. The modern state of the industrial development of gas-saturated waters abroad. - On Sat. "Resources of unconventional gas sulfur and problems of its development". - Leningrad. - 1990. - P.138-144). The described installation, in addition to the mentioned features, contains devices for raising water with gas dissolved in it to the surface and for the subsequent extraction of gas from the raised water on the surface of the earth, as well as the use of pipes of increased diameter and means to exclude clogging of pipes with sand.

The disadvantage of the described installation is its significant cost, in terms of manufacturing and high operational costs, associated with the need to raise water with gas dissolved in it to the surface and the subsequent extraction of gas from water already on the surface of the earth. co

The proposed useful model is based on the task of creating such a facility for the extraction of He! of natural gases from gas-saturated underground waters, which would have a lower cost and would require less operating labor costs. The task is solved by creating conditions for the release of dissolved hydrocarbon gases - directly in the aquifer. F

The task is solved by the proposed installation for extracting natural gases from 32 gas-saturated underground waters, intended for its installation on a well, and contains the main casing - a column, the lower end of which is intended to be located in an aquifer, and, according to the proposal, the main casing column has a section perforation, intended for its location in the location of the rock salt layer, an elevator column installed in the main casing, the lower end of which is designed for its location on the upper boundary of the aquifer, a circulation packer installed in the intertube, the upper end of the main of the casing string is equipped with a head and preventer, and the installation is equipped with a pumping station designed to supply fresh or slightly mineralized water to the intertube. with" The authors experimentally discovered the effect of the release of natural gas from the water in which it is dissolved during the change in the mineralization of such water - the "salting out" effect. The proposed method allows, using the "salting out" effect, to obtain natural gas from the water in which it is dissolved, directly in the aquifer. That is, the extraction of natural gases from gas-saturated groundwater occurs without transporting such water to the surface of the earth. (Te) The essence of the proposal is explained in the drawing, which schematically shows the installation for extracting natural gases from gas-saturated groundwater. b The installation is installed on a well equipped with the main casing string 1. The main casing (Te) 20 string 1 passes to the water-bearing layer 2. In the location of the rock salt layer C, the casing string 1 is perforated - a perforation section 4 is created in the main casing string 1 an elevator column 5 is installed, the lower end of which is located on the upper boundary of aquifer 2. A circulation packer b is installed in the interpipe, and the wellhead is equipped with a head and preventer 7. The installation is equipped with a pumping station designed to supply fresh or weakly of mineralized water /not shown/, as well as 29 units of complex gas preparation 8 /"UKPG/" designed for purification, drying and compression, the output of which is connected to the natural gas consumer's gas pipeline /not shown/. As UKPG 8 can be used traditional aggregates of the same purpose, which are used on main gas pipelines (Information of the sector of RNTI ODO "NPO named after M.V. Frunz e", "Gas pumping units, compressor stations and installations for the gas and oil industry" RVA "Computer Systems", 1999, Ukraine, p. 60 13).

The proposed setup works like this. An area with rock salt deposits is preliminarily determined, where the aquifer contains an industrially suitable amount of dissolved hydrocarbon gases. A well is built, equipped with a main casing string 1, which is passed to aquifer layer 2. In the place of the rock salt layer, the casing string 1 is perforated, forming a perforation area 4. A lift column 5 is buried in the well to the aquifer layer 2. In the inter-pipe a circulation packer 6 is installed, the wellhead is equipped with a head and preventer 7. Fresh or weakly mineralized water is supplied to the interpipe with the help of a pumping station, which during its passage through the layer of rock salt C is saturated with salt and enters the aquifer in the form of brine 2 with dissolved gas.

At the same time, in aquifer 2 with dissolved gas during the change in water mineralization, gases are released that enter the elevator column 5, since the inter-pipe is closed for the movement of gas by the circulation packer 6. The gas that rises through the elevator column 5 enters the UKPG 8. The mentioned gas rising through the lift column 5 also carries out part of the formation water according to the principle of gas lift.

UKPG 8 was used to separate water from gas. The water separated in UKPG 8 is again supplied to the intertube.

Such water is pumped to horizons located above the aquifer 70 2 with gas.

The gas from the elevator column 5 entering the UKPG 8 is cleaned, dried and compressed in it, and then supplied to the natural gas consumer through the gas pipeline.

After the start of intensive gas release, the supply of brine to the aquifer 2 can be significantly reduced or even stopped until the reduction of the gas flow rate is recorded, since the exit of water by the gas lift from the aquifer 2 reduces the pressure in the formation and, as a result, promotes the free release of gas.

Claims (1)

Formulation of the invention Installation for extraction of natural gases from gas-saturated groundwater, intended for its installation on a well containing a main casing string, the lower end of which is intended to be located in an aquifer, which is characterized by the fact that the main casing string has a perforation area intended for its location at the location of the rock salt layer, an elevator column installed in the main casing string, the lower end of which is intended for its location on the upper boundary of the aquifer layer, a circulation packer installed in the inter-pipes, the upper end of the main casing string equipped with an Ogolovk and a preventer, and the installation is equipped with a pumping station designed to supply fresh or slightly mineralized water to the inter-pipe. - (ee) (o) (Se) (o) yo - and? - se) (o) se) IR e) 60 b5