RU2145664C1 - Method of developing fractured oil formation - Google Patents

Abstract

FIELD: development of oil deposits, particularly, methods of heat stimulation of fractured formations containing high-viscosity oil. SUBSTANCE: method includes driving of mine working below oil formation and two gently rising injection and producing wells. Injected into injection wells is steam until temperature in producing wells reaches maximum permissible value excluding formation of vapor at current formation pressure. During steam injection into injection wells withdrawal of oil from producing wells is discontinued. Then steam injection is stopped, and oil withdrawal from producing wells is started and continued until temperature of withdrawn fluid drops to value below which oil viscosity sharply rises. Oil withdrawal is discontinued and steam injection and oil withdrawal cycles are repeated. EFFECT: reduced heat losses and improved temperature conditions in mine workings due to prevention of steam break through formation fractures. 3 dwg

Description

 The invention relates to the development of oil fields, in particular to methods of thermal exposure of a fractured formation containing highly viscous oil.

 There is a method of in-situ development of viscous minerals (Canadian patent 1173356, class 166-39, 1985), in which mine workings are constructed below the oil reservoir, from which half-inclined (horizontal) wells are drilled and steam is injected into them, alternating with selection oil. This method is intended for the development of non-fractured deposits of inactive bitumen.

 The disadvantage of this method is that the steam is pumped under high pressure. This will lead to steam breakthroughs into the mine workings and beyond the boundaries of the developed areas along the cracks. The consequence of this is large heat loss and a deterioration of the temperature regime in the mine workings. Another disadvantage of this method is that oil is taken from the same wells into which steam is pumped. This will inevitably lead to the selection of liquid with a high temperature close to the temperature of the injected steam, especially at the beginning of the selection cycle, as a result of which heat losses to the mine workings will increase and the temperature regime will deteriorate in them.

 A known method for the development of oil fields (SU 1805212 A1, E 21 B 43/24, 04.01.90), in which the coolant is injected into the formation and oil is taken from it through the hollow rising wells drilled from a mine located beneath the oil reservoir, vertical wells are drilled, all wells are divided into groups, each of which covers the entire volume of the developed formation, the coolant is injected into separate groups of wells, while simultaneously taking oil from the remaining groups of wells.

 The disadvantage of this method, taken by us as a prototype, is that steam injection and oil extraction on the area of the developed section are carried out simultaneously.

 As a result of this, steam will break through cracks into production wells, and through them into mine workings, which will lead to large heat losses, a sharp deterioration in the temperature regime and working conditions of personnel working in the mine.

 The objective of the present invention is to reduce heat loss and improve the temperature regime in mine workings by preventing steam breakthroughs in the fractures of the formation.

 The problem is also solved by the fact that the cycles of steam injection and oil extraction throughout the entire area of the developed section are alternated, i.e. when steam is injected into injection wells, the selection of oil from production wells is stopped.

 The problem is also solved by the fact that the steam is injected into the injection wells until the temperature in the producing wells reaches the maximum permissible value, which excludes the formation of steam at the current reservoir pressure, after which the steam injection is stopped and oil is taken from all the producing wells of the area , which is conducted until the temperature of the produced liquid drops to a temperature below which the viscosity of the oil begins to increase sharply, then the selection of oil is stopped and further pumping cycles macaws and selection of oil is repeated.

Salient features of the claimed invention are:
- cycles of steam injection and oil extraction over the entire area of the developed area are alternated, and during the period of steam injection into injection wells, oil is not taken from production wells;
- steam injection is carried out until the temperature in the producing wells reaches the maximum allowable value, excluding the formation of steam at the current reservoir pressure, after which the steam injection is stopped and oil selection begins;
- the selection of oil is carried out until the temperature of the produced liquid drops to a temperature below which the viscosity of the oil begins to increase sharply, and during the period of the selection of oil, steam injection is stopped throughout the developed area.

 The above distinguishing features in combination with the known ones allow us to solve the problem posed by the invention, namely to prevent steam breakthroughs through cracks in the mine workings and outside the developed area, and suggest that the claimed combination of features is considered to be "New".

 The claimed distinguishing features of the invention are innocuous to the average person skilled in the art. In this regard, we believe that the claimed invention has an "Inventive step". The invention is “industrially applicable”, since the available domestic equipment and technology developed by us allow us to use the method in full.

 In FIG. 1 shows a plot of a developed field in plan.

 In FIG. 2 depicts the same section in the context of 1-1 in the transport and preparation of oil in the mine workings.

 In FIG. 3 depicts the same area when transporting oil through a special well drilled from the surface into the gallery.

 An inclined mine 1 is conducted through the oil reservoir, and from it, under the oil reservoir 2, a drilling gallery 3 is constructed, from which a section of the reservoir 2 is uniformly drilled by the half-boreholes, dividing them into injection 4 and producing 5.

 In injection wells 4, steam is injected from the steam generator 6 until the temperature in the producing wells 5 reaches the maximum allowable value, excluding the formation of steam at the current reservoir pressure. Moreover, all producing wells 5 are closed, and the temperature in them is determined using remote temperature sensors. The permissible maximum temperature is determined using the saturated steam table at the current reservoir pressure. When the specified temperature is reached, steam injection is stopped and oil is taken from production wells 5, which are conducted until the temperature of the produced liquid drops to a value below which the viscosity of the oil begins to increase sharply. This temperature is determined using a graph of the dependence of the oil viscosity of a given field on its heating temperature. When the indicated temperature is reached, the oil selection is stopped, and further the steam injection and oil extraction cycles are repeated.

Example. The claimed method can be implemented on the Yaregskoye field of high viscosity oil with a fractured reservoir. The viscosity of oil at an initial reservoir temperature of 6-8 ^o C is 15 thousand mPa • s, and when heated to 100 ^o C it decreases to 30 mPa • s. The productive layer lies at a depth of 130-250 m and has an average oil-saturated thickness of 20 m. The field was previously drilled by the mine method in natural mode, and the field is currently undergoing secondary development by the thermal mine method. The reservoir is opened by a system of mine workings (mine shafts, floor drifts), passed above the oil reservoir.

 To implement the method in such conditions, inclined workings 1 3-5 m below the bottom of the oil formation 2 are passed from floor drifts from floor drifts (Fig. 1, 2). A drilling gallery 3 is constructed from the inclined hole 1 under formation 2, from which three tiers of rising wells are drilled through the formation from 50 to 250 m in length, 40 wells in each tier. All wells to the bottom of the oil reservoir are lined with pipes with a diameter of 168 mm, which are cemented with heat-resistant cement. Wells in the middle tier 4 are used as injection wells, for which they are equipped with a column of pipes with a diameter of 50-60 mm for 2/3 of the length of the well and then connected to a steam manifold 8, which in turn is connected to a steam supply well 7 connected to a steam generator 6 installed on the surface of the earth. The wells of the lower and upper tiers 5 are used for oil production, for which they are connected to the oil collector 9, through which oil enters the tank 10, from where it is pumped by pumps 11 through the pipeline 12 to the mine oil collectors, where oil is prepared and transported to the surface.

In FIG. 3 depicts an embodiment of a method in which the produced fluid is immediately pumped down the well 13 to the surface, a submersible pump 14 is lowered into the sump of this well. Oil is prepared in the tanks 15 on the surface and then transported to an oil refinery. In this embodiment, the entire development cycle of the formation, including steam injection and oil extraction, is carried out from the surface, the use of underground structures (mining, pump chambers, oil pipelines and oil reservoirs) is excluded. After drilling and equipping the developed section of formation 2, steam is injected into injection wells 4 at a pressure of 0.5-1.0 MPa, while monitoring the temperature in production wells 5 using remote temperature sensors, while production wells 5 are closed by shutoff valves at their mouths. After the temperature in the producing wells reaches 120 ^o C (the boiling point of water at a reservoir pressure of 0.2 MPa), the steam injection is stopped and oil is taken from all the producing wells of the site, while continuing to control the temperature in the producing wells 5. After the temperature in the producing wells drops to 70 ^o C (with a further decrease in temperature, the viscosity of the oil begins to increase sharply), the selection of oil is stopped and the steam injection cycle begins again. Subsequently, the cycles of steam injection and oil recovery are repeated. The development of the reservoir lead to an economically viable limit. To prevent heat loss from the gallery 3 in the mine workings of the mine in the inclined workings 1 construct insulating jumpers 16 (Fig. 1 and 2).

Claims (1)

 A method for developing a fractured oil reservoir, including drilling a mine below the oil reservoir, drilling from it half-rising injection and production wells into the oil reservoir, injecting steam into them and taking oil, characterized in that during the period of injecting steam into the injection wells, the selection of oil from producing wells, and steam injection is carried out until the temperature in the producing wells reaches the maximum permissible value, excluding the formation of steam at the current reservoir pressure, after whereupon the steam injection is stopped and oil is taken from all the producing wells of the section, which are kept until the temperature of the produced liquid drops to a temperature below which the viscosity of the oil begins to increase sharply, then the oil selection is stopped and further the steam and oil extraction cycles repeat.

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