SU775297A1 - Filterless well construction - Google Patents

Description

The invention relates to the field of drilling wells for water (oil) and can be used in the search, exploration and exploitation of groundwater (oil) .5

In modern technology, the construction of filterless wells on water for operational, prospecting and exploration purposes often uses a filterless method of operating underground water, which consists in introducing no more than 0.5 m into the flooded sand below the waterproof roof below. operational (water-intake) pipe string and | 5 by intensive pumping of an airlift; volume or flushing, creating a sandy water flow from the bottom upwards, a cavity is developed in the upper part of the aquifer; with a large water intake well l.

The closest technical solution is a well design that includes a casing, a lifting string, and a settling basin fixed to the lifting string with metal rods so that side receiving windows are formed. This leads to the formation of a distance-30 process.

the flow of the water-resistant (oil-receiving) cavity, resistant to collapse, 2.

However, during operation (testing) of the lower part of the aquifer (oil-bearing) layer, located directly on the impermeable (oil-resistant) layer, as well as with frequent alternation of relatively thin water-bearing (oil-displaced) sandy (gravel, pebble) layers with impermeable (eg, clay) layers The exact installation of the water intake windows of the production column opposite the interval being tested becomes difficult and the windows may mistakenly turn out to be at the level of the water-permeable (oil refractory), which will limit or even make it almost impossible for water to flow (oil) into the well. In addition, the implementation of a sump with a lifting column increases the flow rate and complicates the design of the well.

The aim of the invention is to simplify the well design.

Claims (2)

The goal is achieved by the fact that the lower part of the lifting column is concentrically placed in the sump with a gap relative to its walls and bottom, and the sump is formed directly by the wellbore in the bottom layer consisting of erosion resistant rocks, such as mudstones. The area of this gap must be not less than the area, the q of the cross section of the inner surface of the production casing pipe. When pumped from the bottom, the inflow of liquid from top to bottom results in a stable closed water-intake (oil-receiving) cavity after a certain time of sanding. The cavity in the further course of operation is not collapsed, the well is not sanding both under constant and variable operation conditions, as well as under pressure and under free-flow conditions. FIG. 1 shows a well after drilling it in a rotational drilling method, a section; in fig. 2 - well design after installation in the settling box of the lifting column and formation of stable ice. The construction includes borehole 1, water sands 2, bottom water-pressure layer 3; a sump 4, a lifting column 5, in which the suction tubes 6 are installed, for pumping out. After completion of the pumping and the formation of a stable water intake 7, the clarified water 8 is pumped out. plantings, for example with an accuracy of 1 m, with an annular side clearance of at least the cross-sectional area of the pipe. Further, in the process of pumping when water moves from top to bottom, the walls of the wellbore partially collapse and the sand fits snugly to the outer wall of the casing water intake pipe, and then a certain volume of sand of the closed water intake cavity is formed above the settling basin, initially without permanent pumping mode. Subsequently, pumping is carried out under variable operating conditions, after several breaks in pumping, for example 3-7, to completely stop sanding, there is no sand in the water at any moment of pumping, after a break, in the beginning, middle, and end of pumping. Further pumping of clarified water for operational or experimental purposes in any operating mode is carried out at flow rates not exceeding the flow rate achieved at the end of the pumping. The use of a lateral gap between the top-open settling tank and the smaller diameter open-down pipe of the production string located in it as the main cavity-forming water-intake (non-thermal) part of the well allows, without affecting the pumping results, to place the lower open end of the production string within . This eliminates the possibility of technical error — the installation of the column in depth, since the depth of its installation becomes largely independent of the depth of the required sampling interval of the horizon. The error in the construction of the sump, the upper end of which should be located at the required depth of testing the horizon, is compensated by the fact that the sump can be a section of the wellbore, passed directly into the impermeable (oil-resistant) layer and above this area the water bearing (oil-bearing) layer will be located. All this expands the boundaries of the use of a filterless method of operating a well fluid, which allows it to be used more reliably when there is frequent alternation of impermeable to the fluid rocks, as well as when a depressurizing water receiving (oil receiving) part of the well is formed in the immediate vicinity of the bottom of the aquifer. Reducing the exact fit requirement of the production string reduces installation time. The absence of side windows in the pipe of the column, as well as, in some cases, a metal sump, which replaces the section of the borehole in water-resistant (oil-resistant) rocks, simplifies the well design, reduces the cost and intensity of work. Claim 1. The design of a filterless well, including a casing, a lifting column and a sump, characterized in that, in order to simplify it, the lower part of the lifting string is concentrically placed in the sump with a gap relative to its walls and bottom. 2. The structure according to claim 1, characterized in that the settling tank is formed directly by the barrel in the subsurface aquitard consisting of erosion resistant rocks, such as mudstones. Sources of information taken into account in the examination 1. Reference book on drilling and equipping wells with water. M., Nedra, 1972, p. 378-381. 2. USSR author's certificate W 403843, cl. Е 21 В 43/08, 07.07.64. l: