RU2007109548A - METHOD FOR DEVELOPING A HYDROCARBON DEPOSIT WITH PHYSICAL INFLUENCE ON THE GEOLOGICAL ENVIRONMENT - Google Patents

Claims (25)

1. A method of developing a hydrocarbon reservoir with a physical impact on the geological environment, including producing reservoir fluids through production wells, identifying zones of anomalous stress-strain state of rocks, exposure to disturbances of mechanical stresses at previously detected dominant frequencies, characterized in that local anomalous sections on high flow rates of wells and accumulated production of oil, and / or liquid, and / or gas, and / or geophysical methods, they produce cycles the impact by disturbances of mechanical stresses at dominant frequencies, and the preliminary duration of the exposure cycles is determined by changing the set of geological and physical parameters of at least one reservoir, and the physicochemical properties and phase states of the fluids saturating it, and the preliminary intervals between cycles are set in accordance with the relaxation time of the phase states of these fluids, then the dominant frequencies and exposure parameters are adjusted about the change in the phase states of reservoir fluids in production wells and / or production rates of production wells and / or changes in the energy level of seismic-acoustic emission of a productive formation, and the total time of the process, including cycles and intervals between them, is chosen until the reaction of production wells stops. 2. The method of developing a hydrocarbon deposit according to claim 1, characterized in that in addition to the deposits, a working agent, for example water, is injected into injection wells. 3. The method for developing a hydrocarbon deposit according to claim 1, characterized in that areas with undeveloped reserves are identified inside local abnormal areas, for example, by constructing a geological-mathematical model and / or maps of the residual oil-saturated thickness of the formations, water cut and / or by changing seismic acoustic emission by local abnormal areas, and inside areas with undeveloped reserves determine the location of the points of cyclic exposure to disturbances of mechanical stress with downward pressure gradients Nia towards producing wells, such as maps isobars. 4. The method of developing a hydrocarbon deposit according to claim 1, characterized in that vibroseismic, and / or electromagnetic, and / or microwave, and / or acoustic and / or pulsed action from the surface of the Earth and / or with the use of downhole generators, and / or hydrodynamic, and / or physico-chemical, and / or thermal effects. 5. The method for developing a hydrocarbon deposit according to claim 4, characterized in that the bottomhole generators are installed in production and / or injection wells, and hydrodynamic, acoustic, electrospark, gasdynamic, electrodynamic, thermogasochemical, thermodynamic, explosive are used as downhole generators. 6. The method of developing a hydrocarbon deposit according to claim 1, characterized in that pulse, and / or wave, and / or pumping units are installed on the bottom of the wells. 7. The method of developing a hydrocarbon deposit according to claim 4, characterized in that cyclic vibroseismic and / or electromagnetic effects on local abnormal areas are carried out simultaneously or alternately from the surface of the reservoir and / or from the wells. 8. The method for developing a hydrocarbon deposit according to claim 1, characterized in that the dominant frequencies, the duration of the exposure cycles and the intervals between them are determined by changing the energy level of seismic acoustic emission from the background value by installing sensors on the surface of the reservoir and / or in the wells and / or in time relaxation of the solubility of gas evolved upon exposure to gas and / or changes in dynamograms in production wells operated by sucker rod pumps before and after exposure and / or changes in gas fact pa and the gas composition in the reacting producing wells. 9. The method of developing a hydrocarbon deposit according to claim 8, characterized in that the duration of the exposure cycles is set to at least the duration corresponding to the maximum value of the gas released from the formation fluids, and the intervals between cycles are shorter than the relaxation time of the solubility of the released gas. 10. The method of developing a hydrocarbon deposit according to claim 1, characterized in that the cyclic effect of disturbances of mechanical stresses at dominant frequencies is produced in areas with the maximum differentiation of the residual oil reserves along the section of the dismembered reservoir and / or reservoirs combined into one development object. 11. The method of developing a hydrocarbon deposit according to claim 1, characterized in that the local abnormal areas are determined by natural and / or induced seismic acoustic emission. 12. The method for developing a hydrocarbon reservoir according to claim 1, characterized in that various technological processes are monitored when the bottom-hole zone and the formation from wells are monitored, based on recording seismic-acoustic emission in the near-wellbore zone of the producing formation and analyzing its signals in real time. 13. The method of developing a hydrocarbon deposit according to claim 1, characterized in that the local anomalous sections are determined by the interaction of the wells with spasmodic changes in their operating modes, available over the past development period, or purposefully created in the reservoir with subsequent statistical processing of their relationship, determination and comparison signal delay time, piezoelectric conductivity and reservoir conductivity coefficients in the directions. 14. The method of developing a hydrocarbon reservoir according to claim 13, characterized in that the injectivity in injection wells, flow rates of liquid, oil and water cut in production wells are selected as operational parameters for statistical processing of well interactions, and a jump-like change in operating parameters of injection and producing wells wells are produced by starting, stopping wells, increasing and decreasing injectivity or flow rate, respectively. 15. The method of developing a hydrocarbon reservoir according to claim 13, characterized in that the period of the analyzed interaction of the wells includes a period of time before the abrupt change in the operating mode of the wells with a duration of at least one discrete step between measurements of the operating parameters of the wells, which is selected according to the frequency of formation of the database according to the operational parameters , and the duration of the well operation in an abruptly changed mode is set comparable with the signal delay time. 16. The method of developing a hydrocarbon deposit according to item 13, wherein the statistical processing of the interaction of the injection and surrounding production wells is performed according to the relative volume of water injected into the injection well with the relative volume of liquid production, as well as the water cut of the production well. 17. The method of developing a hydrocarbon reservoir according to claim 13, wherein the statistical processing of the interaction of the producing wells is carried out according to the relative volumes of liquid, oil, and water cut production. 18. The method of developing a hydrocarbon reservoir according to claim 17, characterized in that the relative volumes of water injected into the injection wells, the relative volumes of liquid, oil production in the producing wells are determined in fractions of a unit to their maximum value for the period of the analyzed interaction of the wells. 19. The method of developing a hydrocarbon reservoir according to item 13, wherein the coefficient of piezoconductivity in the direction is determined by the dependence

where χ is the piezoelectric conductivity coefficient of the formation, m ² / s; R is the distance between the interacting wells, m; t ₃ - the delay time in the direction, s, and the conductivity of the formation in the direction is determined by the dependence

where κ is the permeability of the formation, microns; μ is the viscosity of the reservoir fluid, Pa · s; m is the porosity of the formation, fractions of units, β _W and β _s are the compressibility coefficients of the formation fluid and the formation rock, respectively, 1 / Pa. 20. The method for developing a hydrocarbon deposit according to claim 1, characterized in that the distribution of water and oil saturation in the reservoirs is established by the total change in seismic acoustic emission over the area in different zones of the reservoir. 21. The method of developing a hydrocarbon deposit according to claim 1, characterized in that the action on the reservoirs by disturbances of mechanical stress is carried out continuously or periodically, at time periods associated with the action of global geoplanetary factors on the geological environment, for example, with the action of lunar-solar tides. 22. The method for developing a hydrocarbon deposit according to claim 1, characterized in that the dominant excitation frequencies are selected in the range of 3-500 Hz. 23. The method for developing a hydrocarbon deposit according to claim 1, characterized in that as local anomalous sections, ring subvertical sections penetrating from the depths of the crystalline basement into the reservoir of oil and gas reservoirs and / or sections of the reservoirs with residual oil saturation formed due to the closure of microcracks upon falling are selected reservoir pressure and / or portions of the reservoirs near the arches of structures, and / or on the periclines, and / or wings of the structures. 24. The method of developing a hydrocarbon deposit according to claim 1, characterized in that the gas hydrate deposit is affected by disturbances of mechanical stress simultaneously or alternately with physical stresses and / or with heat carriers and / or with chemical agents. 25. The method of developing a deposit according to claim 1, characterized in that the duration of the exposure cycles on the gas reservoir is not less than the duration corresponding to the maximum change in the stable condensate content, and the intervals between cycles are shorter than the relaxation time of the stable condensate content.