RU2301328C1 - Method for highly-viscous oil production from horizontal well under reservoir treatment with heat - Google Patents

Abstract

FIELD: oil production, particularly to produce heavy oil from reservoirs with the use of heat.

SUBSTANCE: method involves drilling continuous well extending to day surface; installing casing pipe in the well and cementing hole clearance; perforating casing pipe in several intervals and installing tubing string provided with packers at tubing string ends in the casing pipe; arranging packers in front of perforation intervals and performing packer setting in well; supplying heat carrier in flow string from the first well end; producing well product from inlet well end via flow string to provide necessary intake capacity; serially installing packers within perforation intervals from extreme perforation intervals to central one in non-perforated zones; setting packer in well. Heat carrier is fed in reservoir from inlet and outlet well ends via flow strings downstream of the packers. Product is extracted via tube space upstream of the packers up to bottomhole formation zone drainage initiation. Then the well is used as injection or production well.

EFFECT: increased efficiency due to serial interval treatment with heat, extended coverage of heat application and provision of oil displacement from bottomhole formation zone.

2 dwg

Description

The invention relates to oil production using heat, mainly from reservoirs with heavy bituminous oil.

A known method of increasing oil recovery (see patent RU No. 2191895, ЕВВ 43/24, publ. 27.10.02), including the descent into the casing of concentrically two tubing strings, supply through the inner coolant to the end of the casing, supply gas between the casing and the tubing string to the beginning of the horizontal part of the barrel and the selection of products from this part between the tubing strings.

The method allows for the production of oil.

The disadvantage of this method is that when it is used to ensure a given injectivity, high energy costs are required, since energy losses are associated with the transfer of heat taken by the products to be lifted through the tubing string from the coolant supplied to the well, while the depth of the bottomhole zone is small.

There is also known a method of thermal displacement of oil from a horizontal well (see patent RU No. 2067168, ЕВВ 43/24, publ. 09/27/96), including the descent into the well of a perforated casing string, cementing the annulus to the horizontal well, the descent into the casing string of the pump -compressor pipes with a packer, supplying coolant through it to the end of the casing for the packer, taking products through perforation of the casing at the beginning of the horizontal section and lifting it along the annulus.

The known method allows the production of highly viscous oil due to its thermal displacement from a horizontal well.

However, the depth of thermal coverage of the bottom-hole zone and its draining are insignificant at significant energy costs due to the removal of heat from the well with the product after heating the bottom-hole zone.

The closest in technical essence and the achieved result to the proposed method is a method for the production of viscous oil by thermal action on the reservoir (see patent RU No. 2211318, E21B 43/24, publ. 08/27/2003), including drilling a continuous well with an entrance and by leaving it on the day surface, installing the casing in it, annular cementing, perforating the casing, installing tubing strings in it, supplying coolant through them until the oil liquefies around the wellbore, after which the product is selected tion of the outlet portion with continued pumping coolant through an input portion of the well.

The known method allows to increase the depth of thermal impact of the bottom-hole zone and its draining while reducing energy consumption for the implementation of the method.

The disadvantage of this method is that when producing highly viscous, especially bituminous, oil from a horizontal well, the heat exposure along the entire length of the bottomhole zone and its draining remain low at high energy costs, and oil production is ineffective, since when supplying coolant from the input and output sections of the well a sufficiently fast and uniform heating of the entire perforation interval is not ensured due to its different injectivity, and when selecting products for the output section, a significant part of the heat transfer ator supplied from the input section, taken out together with the surface of the product.

In addition, when the coolant is supplied to the well through the tubing string, part of the heat is unproductively lost due to its contact in the annulus with unproductive rocks through the casing.

The technical problem to which the claimed invention is directed is heating the bottom-hole zone to provide a given injectivity of the coolant by moving it along the perforation interval from the input to the output end of the well, increasing the coverage of the formation by heat exposure along the entire length of the bottom-hole zone and its draining due to the interval thermal impact and displacement of oil from the bottomhole zone.

The stated technical problem is solved by the described method of producing highly viscous oil from a horizontal well with thermal effect on the formation, including drilling a continuous well with its entrance and exit to the day surface, installing a casing in it, annular cementing, perforating the casing, installing pump casing in it -compressor pipes, the supply of coolant through them and the selection of products, while the perforation is performed intervalwise, packers are placed at the ends of the tubing columns they are installed in front of the perforation intervals, the well is packaged, coolant is supplied from the inlet end of the well, and products are selected from the outlet to ensure a given injectivity, packers are installed in the non-perforated sections within the perforation intervals, the packer is well, the coolant is fed into the reservoir with inlet and outlet ends of the well along tubing strings for packers, products are taken along the annular spaces in front of the packers until the side is well-groomed zone, after which the well is transferred to the injection or production.

The studies showed that the interval perforation, the placement of packers at the ends of the tubing strings and their installation in front of the perforation intervals, the packing of the well, the flow of coolant from the input end of the well and the selection of products from the output end allow:

firstly, warm the bottom-hole zone and provide the given coolant injectivity under conditions of low mobility of highly viscous, especially bitumen, oil due to heat transfer to the reservoir from the coolant moving along the perforation interval and due to its entry into the bottom-hole zone;

secondly, to begin the drainage of the bottom-hole zone of the formation due to the arrival of heated and liquefied oil from the formation into the wellbore and raising the product to the surface;

thirdly, to reduce heat loss in unproductive rocks by eliminating contact of the coolant with them through the casing, while preventing its adhesion to annular cement due to temperature elongations.

Within the perforation intervals, the packers are packaged in non-perforated sections alternately from the extreme to the middle, the well is packaged, the coolant is supplied to the formation from the inlet and outlet ends of the well through the tubing strings for the packers, and the selection of products along the annular spaces in front of the packers allows warming and routing throughout the bottom-hole zone due to the interval of coolant injection into the formation with an increase in the radius of the thermal impact and displacement of oil from the formation into the wellbore afterwards lifting products to the surface.

The set of distinctive features of the proposed method for producing highly viscous oil from a horizontal well during thermal exposure to the formation allows the bottom-hole zone to be warmed up and the given heat transfer agent to be provided, to cover the entire length of the bottom-hole zone by heat and drain it, reduce heat loss and increase production efficiency.

From the patent and scientific literature we do not know the claimed combination of distinctive features. Therefore, the claimed method meets the criteria of the invention "inventive step".

In Fig.1 shows a diagram of the implementation of the proposed method to ensure throttle response, in Fig.2 - to razredrenii bottomhole zone.

The method is carried out in the following sequence (combined with an example of a specific implementation).

In the casing 1 (see figure 1) from the input 2 and output 3 of the ends of the well lower tubing string 4 and 5 with packers 6 and 7 at the ends. At shallow depths of the reservoir, when the heat loss to the rocks surrounding the borehole during the supply of coolant to the borehole is insignificant, a column of ordinary tubing pipes is lowered, and at large depths a column of thermally insulated tubing is lowered.

Packers 6 and 7 are installed in front of the perforation intervals located in the reservoir in the horizontal part of the trunk, and the well is packaged. From the inlet end 2, a coolant is supplied to the borehole through the tubing string 4, for example, steam which is moved along the perforated section in the casing 1 and rises to the surface from the outlet end 3 along the tubing string 5.

In this case, local heating of the reservoir around the horizontal well occurs and due to thermal expansion, lowering surface tension and viscosity, gravity, hot oil enters the casing through the perforation and, together with the coolant, moves to the tubing string 5, by which it rises to surface from the outlet end of the well 3.

It should be noted that due to the low mobility of highly viscous and especially bituminous oils, the injectivity by the productive reservoir is limited, and the creation of a high injection pressure at shallow depths, as a rule, and the presence of nearby aquifers is impossible due to the risk of hydraulic fracturing and the breakthrough of the coolant into the aquifer reservoir or adjacent well.

With an increase in the radius of heating of the reservoir around the horizontal wellbore, its throttle response also increases, which can be judged by the pressure drop of the supplied coolant at a constant flow rate or by an increase in the flow rate at a constant discharge pressure. Upon reaching the desired injectivity, the flow of coolant through the string of tubing 4 from the inlet end of the well 2 and the rise of production along the string of tubing 5 from the outlet end 3 is stopped. The flow rate of the coolant, as well as the injection pressure in each case is determined by calculation or experimentally taking into account the depth of the reservoir, its characteristics, the proximity of aquifers, the distance between wells, etc.

Within the perforation interval, packers 6 and 7 are installed in the first from the input 2 and output 3 ends of the well, the non-perforated sections 9 and 8 and the well are packaged (see FIG. 2). The coolant is supplied through tubing columns 4 and 5 from the inlet 2 and outlet 3 ends for packers 6 and 7, and the products are taken along the annulus A and B in front of the packers 6 and 7. In this case, the coolant enters the formation through the perforation intervals between the packers 6 and 7, increasing the radius of heating, as well as displacing the heated oil through the perforation intervals in front of the packers 6 and 7, into the annular spaces A and B from sections of the bottomhole zone located between the perforation intervals behind and before the packers 6 and 7. Received in the inter The rubbing spaces A and B raise the products to the surface from the input 2 and output 3 of the well ends. The coolant is supplied through tubing strings 4 and 5 and the products are selected through annular spaces A and B until the above sections or one of the sections of the bottom-hole zone are razed. The degree of razdrenirovany sections of the bottom-hole zone is judged by the water content of the raised products. In each case, the degree of razdreniye is determined on the basis of technological, economic, etc. considerations. After dehydration of these sections or one of the sections of the bottom-hole zone, the flow of coolant and the selection of products from or from them are stopped.

The installation of packers or one of the packers in subsequent non-perforated areas within the perforation interval, packing of the well, supply of coolant and selection of products is carried out similarly to the described method.

Thus, before the bottomhole formation zone is drained within the entire perforation interval, the well is both injection and production, and after that it becomes only injection or only production.

According to the proposed method, interval perforation, placement of packers at the ends of tubing strings, installation of packers in front of the perforation intervals, well packing, supply of coolant through the tubing string from the inlet end of the well, product selection along the tubing string from the outlet the ends allow warming the bottom-hole zone, begin its drainage and provide the given throttle response, while heat losses to the rocks are reduced during transportation of heat sela to the bottom of the well.

Subsequent installation of packers into non-perforated areas from the extreme to the middle within the perforation intervals, packing of the well, supply of coolant to the formation from the inlet and outlet ends of the well for tubing strings for packers, selection of products along the annular spaces in front of the packers allows to cover the entire thermal effect the length of the bottom-hole zone and drain it, while increasing the radius of heating of the bottom-hole zone.

Thus, the application of the proposed method for producing highly viscous oil from a horizontal well allows to increase the efficiency of oil production by increasing the influx of oil from the reservoir and reducing unproductive heat loss.

Claims (1)

A method for producing highly viscous oil from a horizontal well with thermal effect on the formation, including drilling a continuous well with its entrance and exit to the surface, installing casing, cementing the annulus, perforating the casing, installing tubing strings, feeding coolant and product selection, characterized in that the perforation is carried out intervalically, packers are placed at the ends of the tubing columns, they are installed in front of the interval perforations and pack the well, coolant is supplied from the inlet end of the well, and products are selected from the output to ensure a given injectivity, then packers are installed in the non-perforated sections from the extreme to the middle within the perforation intervals and packers are drilled, the coolant is fed into the reservoir from the input and output ends wells along tubing strings for packers, products are taken along the annular spaces in front of the packers until the bottom hole is razed, after which the well dressed in discharge or mining.

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