RU2548881C1 - Method to build well to produce water from soil water-bearing bed - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: to build a well to produce water from a soil water-bearing bed they drive a well 1 to design depth, arrange a soil filter from filtration material 7, and a pump 5 is installed in the well 1. The well 1 is driven with thrust of a perforated pipe 2 with a non-perforated lower end 3 against its bottomhole and wash-out of soil 4 under it with the pump 5. The filtration material 7 is chosen so that dimensions of its grains are more than the diameter of perforations in the perforated pipe 2. Arrangement of the soil filter is carried out simultaneously with well driving, for which purpose the filtration material 7 is leaned against the outer surface of the pipe 2 leaving the soil 4.

EFFECT: increased efficiency of well erection.

7 cl, 1 dwg

Description

The technical solution relates to the construction, in particular, to the construction of a well for extracting water from an aquifer of soil.

There is a method of erecting a well for extracting water from an aquiferous soil, implemented in an intake tubular well according to the patent of the Russian Federation No. 2472901, class. E03B 3/00, E03B 3/12, E21B 19/00, publ. 01/20/2013, including the placement of the perforated casing pipe in the soil so that its perforated section is in the aquifer of the rocks, and the installation of a water-lifting device in it.

In this method of constructing a well, the formation of a soil filter is not provided, due to which, during operation, a relatively frequent cleaning of the well from particles penetrating into it from the soil is required, which causes its relatively low efficiency.

The closest in technical essence and a combination of essential features is a method of erecting a well for extracting water from an aquiferous soil according to the patent of the Russian Federation No. 2001211, class. E03B 3/06, publ. 10/15/1993, including the sinking of the well to the design depth, the arrangement of the soil filter by filling the well with filtration material and the installation of a water-lifting column in the well with an inventory filter and a pump. The well is drilled through the soil reamer, and when the soil filter is equipped after filling in the well with filter material, the latter is pressed into the well walls and into the aquifer by radial compaction of the filter material using the soil reamer used during the well sinking. The operations of filling in the well of filtration material and pressing it into the walls of the well and into the aquifer of the soil are repeated until a core is formed from the filtration material, the diameter of which exceeds the diameter of the compacted zone of the soil formed during the penetration of the well.

The construction of such a well is associated with a large number of relatively energy-intensive sequentially performed operations and the need for appropriate equipment for their implementation. The compaction of the soil and the pressing of filtration material into it contribute to increasing the resistance to penetration of water into the area of its intake, thereby reducing the flow rate of the well. Therefore, the method of construction of such a well has a relatively low efficiency.

The technical task to be solved is to increase the efficiency of the method of constructing a well for extracting water from the aquifer of the soil by combining the operations of drilling the well and forming a soil filter and the possibility of extracting water from the moment it enters the well from the aquifer of the soil without stopping the process of constructing the well.

The problem is solved in that in the method of erecting a well for extracting water from an aquiferous soil, including sinking a well to a design depth, arranging a soil filter from filtration material and installing a pump in a well, according to the technical solution, the well passes through its bottom face with a perforated pipe with a non-perforated bottom the end and washing the soil underneath with a pump, and the filter material is chosen so that its grain sizes are larger than the diameter of the perforation in the perforated pipe, while the triple soil filter is carried out simultaneously with the penetration of the well, for which the filter material is rolled onto the outer surface of the pipe emerging from the soil.

This technical solution allows you to build a well to extract water from the aquifer of the soil (hereinafter referred to as the well) using a pump, which is used later in the water supply system. At the same time, well drilling operations and the arrangement of a soil filter are combined. The soil under the perforated pipe is washed out by bringing the pump inlet openings closer to the soil until the particles of the soil are drawn into the water stream, by which they are brought to the surface, for example, into the sump. At the initial stage of the construction of the well, water is supplied to the perforated pipe from an external source, for example, from the surface of the sump, to ensure the process of washing out the soil. Further, when water from the aquifer of the soil begins to flow to the well and its flow rate reaches the pump capacity, the water supply to the perforated pipe is stopped. The water that enters the well from the aquifer of the soil can be used not only to wash the soil under the perforated pipe, but also for other purposes, for example, for irrigating plantations, i.e. water can be extracted from the moment it enters the well from an aquifer. Partially, the soil penetrates into the perforated pipe and through its perforation with the formation of a gap between it and the walls of the well, into which, under the influence of its own weight, penetrates the filter material that is laid against the outer surface of the perforated pipe exiting the soil. The lower end of the perforated pipe is embedded in the soil without the formation of a gap between it and the walls of the borehole due to the absence of perforation in it. The filtration material is chosen so that its grain sizes are larger than the diameter of the perforation in the perforated pipe and therefore it does not penetrate into the specified pipe. As a result, the perforated pipe is lowered by washing out the soil under it. Particles of soil penetrate the perforated pipe through its lateral surface in the perforation zone and are carried to the surface, forming a space that is filled with filtration material with the formation of a soil filter. In this case, the filter material does not penetrate the perforated pipe and therefore does not interfere with the normal operation of the pump. Thus, they combine the operations of drilling a well and forming a soil filter and provide the possibility of producing water from the moment it enters the well from the aquifer of the soil without stopping the construction of the well.

It is advisable to wear a perforated cup with a perforation diameter less than the diameter of the pump inlets on the pump. This eliminates the overlap of the pump inlets with soil particles whose dimensions are such that they get stuck in these holes. Therefore, the frequency of removal of the pump from the perforated pipe for cleaning it is significantly reduced, which increases the efficiency of the method of construction of the well.

It is advisable to suspend the pump on the rope so that when it comes into contact with the ground, the rope is taut. This eliminates the suction of the pump into the ground. Therefore, the pump is removed from the perforated pipe freely without operations to release it from being clamped by the ground, which helps to reduce the complexity of cleaning the pump, and therefore, increase the efficiency of the method of construction of the well.

It is advisable to fasten the end of the rope free of the pump to the upper end of the perforated pipe. Thanks to such a fastening of the rope, the pump and the perforated pipe are introduced into the ground synchronously. Because of this, the need to control the length of the rope during the drilling of the well is eliminated, which increases the efficiency of the method by reducing the complexity of the construction of the well.

It is advisable to use crushed stone as filter material, for example, fractions greater than 20 mm. Due to this, during the construction and initial operation of the well, a filter is formed around the perforated pipe in the area of groundwater inflow to it, including crushed stone and relatively large particles of soil stuck in it, which have high throughput, which increases the efficiency of the method due to increased well flow rate .

It is advisable to wash the soil under the specified pipe with water entering the well from the aquifer of the soil, which, after its removal by the soil flow to the surface, is used for consumption. This provides a combination of operations to further deepen the well and produce water, and also reduces the time before the start of water extraction from the aquifer of the soil, which increases the efficiency of the method of construction of the well.

It is advisable from the moment water enters the well from the aquifer of the soil to limit the rate of penetration of the well by the consumed flow rate of produced water. This eliminates the idle discharge of produced water, which significantly reduces the energy intensity of the further deepening of the well and, therefore, increases the efficiency of the method.

The essence of the technical solution is illustrated by an example of a method for constructing a well for extracting water from an aquiferous soil and a drawing, which shows a diagram of a well being constructed in longitudinal section.

The method of construction of a well for extracting water from an aquifer of the soil is implemented as follows.

At the site of the well’s erection, a well 1 passes through the bottom of the perforated pipe 2 (hereinafter referred to as pipe 2) with an unperforated lower end 3 (hereinafter referred to as end 3) and the soil 4 washed out under it by pump 5 through the hose 6 connected to it. At the initial stage of construction wells to ensure the process of leaching of soil 4 into the pipe 2 serves water (not shown). Simultaneously with the penetration of the well 1, a soil filter is arranged, for which purpose filter material 7 (hereinafter referred to as material 7) is placed on the outer surface of the pipe 2 exiting from the soil 4, the grain size of which is larger than the perforation diameter 8 in the pipe 2. A perforated glass 9 is put on pump 5 the diameter of the perforation (not shown in the drawing) is less than the diameter of the inlet openings of the pump 5. The pump 5 is suspended on the rope 10 so that when it comes into contact with the ground 4, the rope 10 is taut. The end of the rope 10 free from the pump 5 is fixed on the upper end of the pipe 2. As the material 7, crushed stone is used, for example, fractions greater than 20 mm. To purify water 11 from the soil 4 carried out by it on the surface of the soil 4, a settling tank 12 is installed, from which, if necessary, part of the water 11 enters through the pipe 13, hose 14 and material 7 into the pipe 2 through its perforation 8. From the moment it enters the well 1 water 11 from the aquifer of the soil 4, the water supply to the pipe 2 is stopped. After this, the washing out of the soil 4 under the pipe 2 is carried out with water 11, which enters the well 1 from the aquifer of the soil 4, which, after its removal by the flow of soil 4 to the surface, is used for consumption. In this case, the penetration rate of the well 1 is limited by the consumed flow rate of the produced water 11. When the well 1 reaches the design depth, the pump 5 is raised and left at a distance from the bottom of the well 1 at which soil particles 4 are not drawn into it from the bottom of the well. In this case, the construction of the underground part of the well is considered completed. Next, an area adjacent to the well is arranged arbitrarily.

The easiest way to implement the proposed method is to construct a well in sandy soil 4 and when groundwater 11 approaches close to the surface, for example, when it appears in spring floods at a depth of 1 ÷ 2 m. Under these conditions, pipe 2 is lowered into a previously dug hole at the bottom which has ground water 11. Note, dig a hole as one of the simple and practically convenient options for preparing for the implementation of the method. In principle, the presence of a pit is not necessary. The pipe 2 can be lowered directly from the surface, feeding water 11 into it by any known method. In addition, there are frequent cases when in the spring floods the lowest places are under meltwater (for example, in the form of puddles), during the construction of which a well does not require the supply of water 11 to the pipe 2.

The construction of the well is supposed to be carried out mainly with the aim of creating an individual source of water 11, necessary, for example, in a garden plot for watering plants. Therefore, a significant advantage of the proposed method from the known solutions also consists in the fact that the construction of the well is carried out by simple and the same means, which are then used to extract water 11 from the aquifer of the soil 4. At the same time, a household spring pump of the Rodnichok type 5 can be used on which is worn on a perforated glass 9, made, for example, from a used two-liter plastic bottle. As a sump 12, a second-hand bath is used, in which after the well is erected, water for plant irrigation is used 11. For the manufacture of pipe 2, a column of plastic sewer pipes is used that fixes them against possible separation by screws in the area of their transition pipes. In this case, only the upper part of the lower pipe is perforated (less time-consuming). clogging of the perforation of the glass 9 with soil particles 4. In such cases, the pump 5 is removed from the pipe 2, after which the perforated glass 9 worn on it is cleaned, for example, with an ordinary nail.

The advantage of the proposed method should also be considered that the process of arranging the soil filter adapts to the conditions of construction and operation of the well and proceeds automatically. Under the influence of the flow of water 11 flowing to the well 11, soil particles 4 try to overcome the layer of rubble adjacent to the pipe 2. The smallest particles of soil 5 penetrate through this layer, fall into the pipe 2 and carried through the pump 5 to the surface. Relatively large particles of soil 4 are stuck in the gravel. In this case, the space freed from the soil 4 will be filled predominantly with overlying rubble. The process of arranging the soil filter is a damping process and soon ceases after the completion of the well construction. The dimensions of the soil filter are determined by the properties of the soil 4, the depth of the well and the intensity of water extraction from it 11. Note that with an increase in the performance of the pump 5, the dimensions of the soil filter automatically increase. Such a filter is constantly washed with water 11 coming from the soil 4 to the well and therefore is not clogged with small particles.

A few hours are spent on the construction of a well in sandy soil 4 to the stage at which it becomes possible to extract water 11 from it. Further, the deepening of the well can be carried out by pumping water 11 out of it in the amount necessary for consumption. For example, when using water 11 to irrigate several hundred hectares of land, the well deepens significantly faster than the rate of decrease in the ground water level in summer 11. It is assumed that the maximum depth of the well will not exceed ten meters. The life of the well is practically unlimited due to the constant washing of the soil filter formed around it.

Claims (7)

1. A method of constructing a well for extracting water from an aquiferous soil, including driving a well to a design depth, arranging a soil filter from filtration material and installing a pump in the well, characterized in that the well passes through its bottom face with a perforated pipe with a non-perforated lower end and leaching underneath the soil with a pump, and the filtration material is chosen so that its grain sizes are larger than the diameter of the perforation in the perforated pipe, while the arrangement of the soil filter is carried out tvlyayut simultaneously with the sinking of the well, for which the filtration material privalivayut to exiting the ground outer surface of said tube. 2. The method according to claim 1, characterized in that a perforated cup with a perforation diameter less than the diameter of the pump inlets is put on the pump. 3. The method according to claim 1, characterized in that the pump is suspended on a rope so that when it contacts the ground, the rope is stretched. 4. The method according to claim 1, characterized in that the end of the rope free of the pump is fixed to the upper end of the perforated pipe. 5. The method according to claim 1, characterized in that crushed stone is used as a filtration material, for example, fractions greater than 20 mm. 6. The method according to claim 1, characterized in that the soil is washed out under the specified pipe by water entering the well from the aquifer of the soil, which, after its removal by the soil flow to the surface, is used for consumption. 7. The method according to claim 1, characterized in that from the moment water enters the well from the aquifer, the penetration rate of the well is limited by the consumed flow rate of the produced water.

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