Patent ID: 9677339
Date: 2017-06-13
CPC Classifications: E21B

Claim:
1. A method for developing oil and gas fields using high-power laser radiation for more complete oil and gas extraction, comprising the steps of opening up producing formations in predetermined regions of wellbores by cutting or perforating material of wellbore casing strings using high-power laser radiation with subsequent evaporation of solid and liquid phases of substances contained in the formations and in matrix rock through these openings, wherein optical fiber cables with light energy-emitting working heads on the ends thereof are used as energy transmitting devices, high-power lasers positioned at the surface are coupled to the optical fibers (light-emitting diodes) of the optical fiber cables and regions with a predetermined high temperature and a high pore pressure are generated in the formations in order to increase the degree of extraction of oil and gas, wherein the process of treating the field formations with high-power laser radiation is repeated multiple times with time intervals therebetween, wherein a plurality of sectors which are mutually offset from one another by a certain angle are irradiated simultaneously, beams of each sector diverging at a given angle, wherein non-contact and remote control of temperatures, pressures, sizes and shapes of cavities created in the formation layers and their linkage is carried out simultaneously and information about content of evaporated material of the formation layers is being collected, wherein laser equipment is positioned at a predetermined depth in preexisting wells having reinforced walls with casing columns comprising pipes by using pipes with attached pumps or flexible pipes with coiled-tubing units, a plurality openings are drilled in the wellbore walls at predetermined locations via the laser equipment, wherein the plurality of openings comprise elongated drill-holes that are formed at high speed by evaporation and high temperature fracture of formation layers and rock material by high-power laser radiation emitted from the light energy-emitting working heads positioned at tips of drill crowns, wherein the openings are drilled in the neighboring wells towards each other until they cross each other in formation layers and formation rock material, wherein flexible composite drilling rods are repositioned during the drilling process at a predetermined angle of about 0 degrees to at least 180 degrees, wherein a direction of drilling and a repositioning angle of the openings are controlled by a direction of laser radiation beams emitted from the optical fibers, wherein material drilled out of the elongated small-diameter openings is evaporated by the high-power laser radiation, wherein wells are drilled at new formation development fields by mechanical-laser drilling, wherein the optical fiber cables with the light energy-emitting working heads coupled to the high-power lasers positioned at the surface are in internal lumens of mechanic drilling equipment having hollow-type actuating rods and crowns, wherein rock formation material is fractured by the high-power laser radiation emitted from the working heads in order to achieve a desired diameter of the well by treating them with high-temperature laser radiation emitted from the working heads positioned at tips of drill crowns to fracture and evaporate the rock material during the drilling process, wherein secondary laterally positioned working heads are used to simultaneously deposit a reinforcement layer on the well walls by using a high-power laser radiation, wherein the reinforcement layer is made of mixtures of material remaining after evaporation of the material drilled out of the openings and substances and materials prepared at the surface and supplied into the wells, or, in cases of weakened areas or carbonate rocks having cracks and cavities formed therein, the secondary laterally positioned working heads are used to simultaneously deposit one or more reinforcement layers to the well walls, wherein the reinforcement layers are formed from the material drilled out of the openings by extracting it via compressed air from the bottom-holes towards ring deposit welding/burn-off devices equipped with high-power laser radiation emitters, and mixtures of quartz sand with substances and materials supplied to the wells from the surface to be melted on walls of wells to improve their quality and toughness, wherein the material drilled out of the openings is completely evaporated and mixtures with ingredients prepared at the surface are supplied to the wells and are deposited on the well walls via ring deposit welding or burning-off devices equipped with secondary laterally positioned working heads having high-power laser radiation emitters located at specified distance from working heads centrally positioned at the tips of the crowns of the drilling tools, wherein the secondary laterally positioned working heads are moved radially and rotationally separately or together with hollow-type actuating rods, wherein, after the drilling of wells to a desired depth is completed, the well walls are polished by removing the artificially created reinforcement layers of the well walls and creating smooth wall surfaces, and creating consistent diameters along the entire length of the wells, wherein well repairs are carried out by cleaning the well walls, pipes with pumps or other field equipment via tubing pipes and other field equipment from asphalt, tar and paraffin deposits by melting and evaporating them with high-power laser radiation while repeatedly moving multi-sided laser radiation emitters along the pipes or wells in a downward and then upward direction, wherein at fields that were opened by drilling wells in oil and gas and other layers via the laser-mechanical drilling diameters of vertical, angular or horizontal production wells are gradually increased by laser-mechanical drilling equipment having expandable well wideners, wherein the artificial layers made out of mixtures of well material and deposited on the well walls during the drilling process to reinforce the walls are removed to increase areas of oil and gas inflow from the formation layers into the wells, wherein diameters of production wells are repeatedly increased and multiple layers of specified thickness having asphalt, tar and paraffin deposits accumulated therein during the field development are removed from the well walls to improve filtration of oil and gas from the formation layers into the wells, wherein diameters of the wells are increased to maximum sizes possible under particular formation layer conditions and capabilities of the laser-mechanical drilling equipment, wherein within the oil and gas and shale layers, in particular, within layers having low permeability and porosity, after diameters of production wells are increased to their maximum, elongated drill-holes having small diameters are drilled in well walls by the high-power laser radiation equipment, to increase areas of inflow of oil and gas into the wells and to increase extraction from the formation, wherein, during treatment of formations having multiple oil and gas layers, diameters of production wells are gradually increased based on power, outstretch and falling within one or more layers being treated, and elongated drill-holes with small diameters are drilled therein, while neighboring formation layers located above or below the layer being treated and not having drilled wells and drill-holes are under-holed or over-holed to cause shifts of formation rock material between neighboring layers and within layers, to change crack systems within the rock material and to change stressed-deformed state thereof, to form oil and gas cross-flow channels between the formation layers and the drilled production wells in the neighboring layers that are being treated to speed up treatment of all layers within the formation with significantly lower costs and time consumed, wherein, in the presence of high-viscosity oil at the fields, a temperature and a pressure within the layers are increased, and a viscosity of oil is decreased by applying high-power laser radiation to spaces between the layers through production wells and elongated drill-holes having small diameters by inserting a plurality of optical fiber cables therein, wherein the production wells and the elongated drill-holes having small diameters drilled in the well are positioned at a specific distance from each other based at least in part on power, outstretch and falling of the layers, and wherein the number of the production wells and the drill-holes drilled therein is increased and a distance between them is decreased to achieve and maintain a target level of extraction of oil and gas from the formation field.