RU2070962C1 - Method for development of geothermal deposit - Google Patents

Abstract

FIELD: withdrawal of geothermal resources and return of processed stratal water to developed horizon. SUBSTANCE: method for development of geothermal deposit includes determination of interacting wells. Filtering channels between them are washed with aqueous solutions of acid compositions and surfactant improving their water conduction. Heat is removed by circulation of stratal water between interacting wells by regulation of their operating conditions and injection of water in compliance with variation of intensity of hydrodynamic and thermodynamic interaction of the wells. EFFECT: higher efficiency. 3 cl, 1 dwg

Description

 The invention relates to methods for developing geothermal deposits, and more specifically to methods for creating geothermal circulating systems (GCC) for extracting heat from deep formation water and heated rocks of the formation skeleton.

 In the context of a sharp rise in price of traditional types of fossil fuels (oil, gas, coal), the competitiveness of geothermal energy increases significantly.

 Recoverable reserves of geothermal resources revealed by drilling can replace a significant part of expensive fossil fuels not only for heating greenhouses, hotbeds, livestock complexes and residential buildings, but also in some regions (for example, in the Caucasus, in the BAM zone, in Kamchatka, etc.) , to create geothermal power plants (GeoTES).

 Given the possibility of extracting thermal and superheated formation water from a huge fund of watered deep oil and gas wells (as well as from liquidated and inactive deep exploration prospecting, parametric and other wells), the use of alternative geothermal energy has great prospects.

 A radical method of protecting the environment (land, water and air) from the harmful ingredients (and thermal effects) of mineralized formation water is the development of geothermal deposits with the creation of geocirculation systems (GCC), providing for the production of formation coolant (thermal or superheated water, steam) through production wells I’ll take heat from it (in heat exchangers) and re-inject chilled formation water into the developed horizon through injection (injection) wells. The creation of GVCs provides not only the most rational solution to environmental protection problems of geothermal production, but also a significant increase in the recoverable heat reserves of geothermal deposits due to the maintenance of reservoir pressures (RPM) and the removal of heat from the skeleton of reservoir rocks.

 An analogue of geocirculation technology for the development of geothermal deposits is the method of developing oil fields with water injection that is widely used in oil production and it would seem that the creation of a GVC does not present any special technical difficulties (Reference book on oil production, edited by Sh.K. Gimatudinova, M. Nedra , 1974, p. 84).

However, due to the relatively low specific thermal potential of the geothermal coolant (water, steam) compared with traditional concentrated forms of fossil fuels (oil, gas, coal), the economic efficiency of developing geothermal deposits with the creation of GVCs is achieved with significantly high production rates of production wells and, accordingly, high stable injectivity of injection wells (injection) wells in the GVC (at least 1000 m ³ / day in each well with a pressure at its mouth of not more than 6.0 MPa), while Namely, the modes of water injection into injection wells for the reservoir pressure maintenance (injection volumes and pressures) are limited only by the requirements for more complete and uniform displacement of oil from the formation to production wells, and the pressure value of water injection into the oil formation is practically unlimited (for example, design development modes with The PPD of many oil fields is provided even when 200 300 m ³ / day of water is injected into each injection well with an injection pressure of 8.0 12.0 MPa, and sometimes up to 30.0 MPa).

 This is due to the fact that the critical level of economically viable capital and operating costs for the extraction of oil (gas, coal) is many times higher than for the extraction of geothermal coolant (thermal water, steam).

 The accumulated experience in the development of geothermal resources identified in various mining and geological conditions suggests that the main condition for ensuring the effectiveness of GVC in geothermal horizons is the high injectivity of injection (injection) wells for returning waste water (after heat removal) to the developed horizons.

 There is also a known method of developing a geothermal field, including extracting formation fluid from the developed horizon, re-injecting cooled formation water into it and conducting hydrodynamic studies (ed. St. USSR N 1201493, class E 21 B 43/24, publ. 1985).

 At the same time, experience in the development of geothermal deposits shows that in order to create effective GVCs in many heat-absorbing reservoirs with high water yield, composed of terrigenous vapor-permeable heterogeneous strata of clayed sandstones, it is not possible to provide satisfactory injectivity of wells when injecting their own produced water (the geothermal deposits Mostovsky, Kazmin Ascension, Novoyaroslavsky, Maykop, Central Burunnoe and others).

Numerous activities carried out in such wells in order to increase their stable injectivity (impacts on formations using variable pressure methods, repeated perforations of casing strings in the intervals of occurrence of aquifers, repeated clay-acid impacts on them, treatment with surfactants, etc.) did not give satisfactory results . Attempted attempts to break thermo-aquatic sandstones (for example, in well No. 16 Mostovskaya) by increasing the pressure in the wells to 0.8 R _mountains . (where P _mountains . vertical rock pressure at the depth of the sandstones) were also unsuccessful (apparently, the failures are explained by the fluidity of the clay confines hydraulically connected to the well, between which sandstones lie, and the compression of the latter by the water confines in the borehole zone).

 It is obvious that under the conditions of heterogeneous (in thickness and strike) terrigenous strata in thermally bearing clayey sandstones in the absence of a well-developed network of natural fractures in the rocks, it is necessary to develop new economical methods for creating GVC.

 The aim of the present invention is to develop an economical way to create a GVC in heterogeneous thickness and strike of terrigenous horizons of thermally bearing sandstones with clay inclusions in the absence of natural fracturing of rocks.

 This goal is achieved by the fact that a complex of single and group hydrodynamic studies of wells with water releases and injections determines the interacting wells, the magnitudes and speeds of their interaction, between these wells in the horizon they develop, circulate formation water and wash the filter channels between the interacting wells with surface-active substances and solvents rocks that improve their water conductivity, and the regulation of the operating modes of interacting wells in the caliper during operation, the system is carried out in accordance with a change in the intensity of the hydrodynamic and thermodynamic interactions of the wells, and before a significant change in the directions and costs of the circulating flows in the GVC, they stabilize the temperature and pressure in the developed horizon.

 The proposed method for creating a GVC differs from the known one in that heat removal from the geothermal horizon is not carried out by frontal displacement of the thermal water contained in it to production wells and it is replaced by cooled formation water pumped into water injection wells, but by targeted research, the selection of interacting wells and circulation of the pumped into the geothermal horizon water between interacting wells in accordance with the intensity of their interaction.

Another difference is that the water conductivity of existing natural filtration channels between interacting wells (for example, along ancient buried beds of washed sand in terrigenous clay-sand sediments) is improved by the repeated circulation of weakly concentrated (up to 10%) acid compositions in formation water containing stabilizers and inhibitors react with species (e.g. mud acid inhibited mixture of hydrochloric acid and hydrofluoric acid of HCl, HF, with the addition of acetic acid CH ₃ COO as a catalyst-inhibitor of the reaction of clay acid with sandstones and clayey rocks) and aqueous solutions of surface-active substances (surfactants) such as OP-10, E-30, pre-cell W -OF-100, etc., as well as mixtures of surfactants with 1 2% hydrochloric acid acid, scale inhibitors and corrosion.

 For each specific chemical and mineralogical composition of the rocks and formation water saturating these rocks, one should select its optimal composition and concentration of acid composition and surfactant taking into account the reservoir temperature, as well as the optimal mode of their injection (pressure and flow rate) into injection wells, providing an effect on the filtration channels along their entire length between interacting wells.

 Improving the conductivity of the filtration channels between the interacting wells in the developed horizon allows reducing the energy costs of pumping water into it during the operation of the GVC, and the heating of the water circulating in it to the formation is ensured by its heat exchange with the formation water saturating the rock and the rock skeleton along the path of its filtration between interacting wells and cursing the operation of wells in accordance with the intensity of their interaction.

 Naturally, during the period of exploitation of the geothermal horizon, other wells, previously isolated from them, that have opened this horizon, will be involved in the system of interacting wells, in particular due to the appearance of thermobaric gradients in its thickness and strike.

 In contrast to the known method of creating a GVC according to the proposed method, the directions and costs of circulating flows in the geothermal horizon during its development are adjusted depending on changes in the number of interacting wells and the intensity of their interaction, as well as when the temperature potential of the recovered coolant decreases, which allows to increase the total recoverable reserves geothermal resources, as this ensures not only the redistribution of circulation flows in the filtration channels crystals between communicating wells, but also the involvement in the process teplootbora new areas of geothermal horizon. However, a significant change in the directions and costs of the circulating flows in the MCC is carried out after stabilization of its temperature and pressure (for example, after seasonal stops of the MCC).

 In addition, in contrast to the known method of heat removal in the GVC, the proposed method allows you to process the filtration channels between wells with scale inhibitors and disinfecting liquids (against sulfate-reducing bacteria), washing these channels after treatment with acid, surfactant, and also periodically during operation of the GVC.

 To illustrate the proposed method for creating a circulation system for the development of the Mostovskoye geothermal field, a part of the structural map is given for the top of the thermal-water horizon of Albian Lower Cretaceous sandstones with mapped wells providing thermal water intake from this horizon since 1970.

The main operational object of the Mostovo thermal water intake (TVZ) is the upper watery sandy mass (member a) of the Lower Albian layer of the Lower Cretaceous sediments. Sandstones are quartz-glauconitic, medium- and fine-grained with a predominance of the clay phase at the roof and sole, and the thickness of the sandstones is divided into two packs (packs a ₁ and a ₂ ) with a clay layer 7 12 m thick, having the same filtration parameters and water quality, which indicates their good hydraulic connection with each other within the TVZ.

During the period of operation of the TVZ, the reservoir pressure of the thermally-bearing horizon has significantly decreased due to the intensive withdrawal of thermal water without artificially replenishing its reserves by re-injection of produced water after heat removal. So, if at the beginning of operation of the TVZ wellhead static pressure P y. Art. in wells averaged 0.8 MPa, it currently stands at 0.35 MPa at the beginning of the heating season and 0.2 MPa at the end of this season. The production rates of production wells are 1000 ^o C 1200 m ³ / day (from each well) and are mainly due to the effect of a thermal lift (average temperature of thermal water in wells T _cf. ≈ 75 ^o C, and the calculated thermal water density corresponding to this temperature is ρ _cp ≈ 986 kg / m ³ .

Due to the drop in the reservoir pressure of the TVZ over the period of its operation and with the aim of introducing environmental protection technology for its development, the creation of a GVC made a large amount of analytical, theoretical and field studies, but they did not give practical results due to the low stable injectivity of the wells when injecting formation water into them ( no more than 350 m ³ / day.).

Estimated calculations show that, in order to ensure the profitability of the operation of GVCs under the conditions of the Mostovsky TVZ, the stable injection rate of each injection well should not be lower than 1000 m ³ / day at an injection pressure of not more than 4.0 MPa.

 To ensure such injection regimes of waste produced water, the proposed method involves the identification of interacting wells and intensification of the conductivity of the filtration channels of the thermally water-bearing horizon between these wells by circulation of aqueous surfactant solutions and weakly concentrated acid compositions, and it is advisable to inject them to the wells that have opened the thermally-water-bearing horizon for more high hypsometric marks.

 For example, if hydrodynamic studies revealed the interaction of wells 1t, 2t, 3t, 7t, 9t and 11t, then it is advisable to use wells 1t, 3t and 9t to inject surfactants and acid compositions, with the rise of these compounds along the remaining 2t, 7t wells interacting with them , 11t.

 As TVZ develops, other wells (for example, 8t, 10t, 13t, 14t and others) will be involved in the geocirculation system of these interacting wells (for example, by changing the thermobaric conditions), which will allow for greater coverage of the heat-bearing horizon by heat removal by adjusting directions and costs in it circulation flows between all interacting wells, if necessary, processing filtration channels between individual surfactant wells and acid compositions.

 The technical and economic advantages of using the proposed method for creating a circulation system for the development of a geothermal field are that it can significantly reduce the capital and energy costs of ensuring an environmentally friendly process of heat removal from geothermal horizons composed of heterogeneous terrigenous porous-permeable layers of clayey sandstones. The method can also be used to intensify GVCs created in fractured, high-temperature strata of carbonate rocks.

Claims (3)

 1. A method of developing a geothermal field, including extracting formation fluid from the developed horizon, re-injecting cooled formation water into it and conducting hydrodynamic studies, characterized in that when developing heterogeneous terrigenous formations composed of thermally-bearing clayey sandstones, interacting wells are determined in the process of hydrodynamic studies and the intensity of their interaction within a single underground hydrodynamic system is porous of the reservoir, between the selected wells, the formation water is circulated and its filtration channels are washed with solvents of the formation rocks and surfactants that increase their water conductivity, and then the modes of operation of the wells are regulated in accordance with changes in the intensity of their hydrodynamic interaction, and the directions and costs of the circulating flows are adjusted depending on the change in the number of interacting wells and the magnitude of their interaction and / or with a decrease in temperature entsiala extracted fluid.  2. The method according to claim 1, characterized in that the change in the directions and costs of the circulating flows in the developed horizon is carried out after stabilization of its temperature and pressure.  3. The method according to PP. 1 and 2, characterized in that scaling inhibitors and disinfectants are periodically introduced into the filtration channels of the geocirculation system between the interacting wells.