RU2241730C2 - Method of injection of a dense additive into boreholes and a composition of the additive - Google Patents

Abstract

FIELD: drilling of boreholes and a dense additive injection.

SUBSTANCE: the invention presents a method of preparation and composition of the improved additives to be injected into boreholes with the purpose for usage of a material to control sorption and-or leakage of a drilling mud during operations of boring. The additive is formed so that it could be injected into the drilling mud with a much higher speed, than powdered or ground additives from similar components. The dense additive is produced from a material used to control sorption and-or leakage of a drilling mud used in the boring operations. The dense additive production stages include the following: comminution of a material used to control sorption or leakage of a drilling mud to produce particles of small sizes and application of a pressure to a material for controlling sorption or leakage of the drilling mud intended for contraction and forcing through apertures with production of a pellet type dense additive. Usually a collateral factor of the process of forcing a comminuted product through the boreholes is heating up of the comminuted material to control sorption or leakage of a drilling mud, during which oils or other binding components may be freed. The technical result is a decrease of a dust formation and increased speed of mixing of the additive at its injection into the drilling mud.

EFFECT: the invention ensures a decrease of a dust formation and increased speed of mixing of the additive at its injection into the drilling mud.

17 cl

Description

BACKGROUND OF THE INVENTION

Field of use of the invention

The invention relates to an improved additive for controlling loss of circulation, absorption and / or leakage of a drilling fluid during drilling operations. In particular, the additive is formed so that it can be introduced into the drilling mud at a much higher rate than powder or ground additives from similar components.

Description of the Related Art

Various additives are known in the art which are used to control the absorption or leakage of drilling fluid during drilling. Although the range of types of additives used for these purposes includes organic to mineral as well as plastic materials, most of these additives are added to the drilling fluid in powder form. The use of powder has several disadvantages. The main disadvantage is that the additive is very light, and this leads to very slow mixing with a high viscosity drilling fluid. When drilling, the rapid introduction of additives into the drilling fluid and pumping it into the well are essential and affect profitability and sometimes safety. To overcome this drawback of slow introduction, silos were equipped with cyclones, venturi nozzles and nozzles to improve mixing and attempts were made to draw additives from the silo into the solution at high speed. Despite advances in technology, mixing is still a relatively slow process. Flow through cyclones is slow, clogging occurs and dusting creates problems. In some regions of the world where dust emission must be zero according to standards, dusting is a significant problem. Even if you move away from the requirements of the standards for the level of dust emission, it should be borne in mind that dust poses a danger to maintenance personnel.

Another problem with conventional powdered additives arises from the usual variations in drilling operations. There is a tendency to conduct underwater drilling at great depths using drilling tools of large dimensions, and large volumes of drilling fluid are required. There is a trend towards the use of more expensive drilling fluids and synthetic oils, which confirms the need for additives with which it would be possible to control the absorption or leakage of the drilling fluid. These factors also have an effect on increasing demand for supplements. However, the amount of storage space, especially in offshore drilling rigs, is a limiting factor.

In the search for the best additives, a large number of organic materials were tested to determine their effectiveness as agents for controlling the absorption and leakage of the drilling fluid. US Pat. No. 4,217,965 to Jim J. Cremins states that cattle food waste can be used as an additive. This organic material is made from husk of raw cotton seeds in combination with flour from cotton seeds, bentonite, some types of cotton lint and surface-active material. When preparing food for cattle, these components are heated and then pressed and extruded into tablets. J. Kremins notes that the advantage of using food waste for cattle is that it eliminates the grinding, chopping and pre-treatment steps required when using other organic waste. Surfactant materials in tablets act as a wetting agent to reduce mixing time without additional chemical additives. Cattle feed pellets are relatively dense and therefore require less storage space. The disadvantage of food waste for cattle is that they do not decompose instantly upon contact with the drilling fluid, but instead retain their shape and structure when added to the drilling fluid. The tablets only begin to disintegrate when they are pumped into the borehole.

There is a need to create additives in a form in which the space required for their storage and / or transportation is minimized. There is a need to create additives in a form in which they mix with the drilling fluid at a significantly higher speed. There is a need for alternative solutions that would minimize or eliminate dust emissions when adding additives to the drilling fluid.

The aim of the present invention is to satisfy these needs. The aim of the present invention is also the creation of additives that would be quickly and efficiently distributed in the drilling fluid with its introduction. These and other objects of the invention will become apparent to those skilled in the art upon reading the present description.

SUMMARY OF THE INVENTION

The present invention has created a method for preparing a dense additive for use in drilling fluids, and also provides a dense additive composition. A method of preparing a dense additive from a material for controlling the absorption or leakage of a drilling fluid intended for use in drilling processes comprises the following steps: grinding the material to control the absorption or leakage of a drilling fluid to obtain small particles; heating the material to control mud absorption or leakage; applying pressure to the material to control the absorption or leakage of the drilling fluid for compaction and forcing through the holes to obtain a dense tablet additive. Although a variety of materials for controlling the absorption or leakage of the drilling fluid is suitable, a preferred embodiment includes organic material as material for controlling the absorption or leakage of the drilling fluid. This tabletted dense additive designed for use in drilling operations, made of crushed material to control the absorption or leakage of the drilling fluid, compressed into a tablet, has a density substantially higher than the density of the crushed material to control the absorption or leakage of the drilling fluid before pressing.

Of organic materials for controlling the absorption or leakage of a drilling fluid suitable for making a dense additive, a preferred embodiment includes cellulosic material. In particular, one or more of the following materials in combination is preferred: crushed wood, pine bark, fruit squeezes, vegetable squeezes, yellow pine, corn cobs, peanut shells, pecans, almond shells, corn cobs, bee wings, cotton weeds impurities, oat husk, rice husk, sunflower husk, sunflower, flax, flaxseed, cocoa beans, feather, peat moss, jute, mohair, wool, paper, sugarcane, cake, sawdust, bamboo, cork tree bark, popcorn ruza, tapioca (cassava flour) and sorghum grain.

A tablet dense additive characterized by increased density preferably has a diameter in the range of 3.175-19.05 mm and a length in the range of 3.175-25.4 mm. The density of the additive is broadly consistent with the material for controlling the absorption or leakage of the drilling fluid, with the preferred density corresponding to the highest compression ratio achieved based on the characteristics of the material. Many organic materials can be compressed so that the density increases approximately two to three times in comparison with the density of the crushed material.

The present invention also relates to a method for performing drilling operations, in which the drilling fluid is circulated in a well drilled in the ground, containing grinding material to control the absorption or leakage of the drilling fluid to produce granules, heating the granules to fluidize naturally occurring binders, forcing the heated granules through holes for forming tablets having a higher density than the density of the material to control the absorption or leakage of drilling th solution, adding tablets to the drilling fluid for circulation in the well. Heating usually occurs as a result of friction during the pressing process. A small amount of heat may also occur during the grinding process. In order to produce certain types of materials to control the absorption or leakage of the drilling fluid, additional heat is desirable. In cases where naturally occurring binders are not present in the materials for controlling the absorption or leakage of the drilling fluid, in a preferred embodiment of the method, the amount of heat generated during processing is minimized and the corresponding binder is added.

Often the sources of fiber used as a material to control the absorption or leakage of the drilling fluid are already in a ground state, such as sawdust. A method of manufacturing a dense additive from such materials to control the absorption or leakage of a drilling fluid comprises preparing unprocessed pulp and compressing the pulp into tablets, for example, having a significantly higher density than the pulp before pressing.

The structure and method according to the present invention, as well as other distinctive features, advantages, benefits and objectives in comparison with other structures and methods known in the art, can be better understood by reading the detailed description below.

DETAILED DESCRIPTION OF THE INVENTION

The present invention has many advantages over traditional methods. Among these advantages, the following can be noted: increased speed at which the additive can be introduced into the drilling fluid; less space required for storage and transportation; reduced emission or complete absence of dust. Distinctive features of the present invention are that the dense additive instantly begins to hydrogenate upon contact with the drilling fluid. With rapid hydrogenation, the dense additive is rapidly dispersed so that it is evenly distributed in the drilling fluid when the drilling fluid is pumped into the well. A preferred embodiment includes the distribution of a dense additive in the drilling fluid using a conventional hopper known in the industry for mixing loose or conventional additives. A typical hopper has an outlet diameter of about 101.6-152 / 4 mm (4-6 inches). The tablets are sized so that they can be easily and compactly poured through the outlet. As with the use of loose additives known in the art, a hopper creates a mixing effect by contacting the dense additive with a liquid. When necessary, tablets can be added to the drilling fluid without the use of a hopper. In this case, the tablets are hydrogenated as soon as they come into contact with the drilling fluid, and instantly disintegrate into fibers or other materials to control the absorption or leakage of the drilling fluid, but the process of mixing the injected drilling fluid into the well takes a longer time to evenly distribute the fibers in liquids. Although the distribution is uneven when the additive is introduced in this way, the additive is immediately ready to perform its function after mixing with the drilling fluid on the surface and the rheological functions of the liquid on the surface are consistent with the properties downhole.

One of the advantages of using compacted additives is the substantial or complete elimination of dust emissions during the introduction of additives into the drilling fluid. When using traditional powders added through a hopper, dust is emitted in large volumes, which poses a danger to the environment and to maintenance personnel. In some regions, for example, the North Sea, there are strict restrictions on dust emission. The use of compacted additives results in a virtually dust-free additive to control the absorption or leakage of the drilling fluid.

Conventional powder or finely divided additives, especially cellulosic additives, have a speed limit at which they can be introduced into the flushing fluid or drilling fluid. This rate of addition is related to the angle of friction of the additive, which limits the speed at which the additive can be unloaded. While previous attempts to increase the introduction rate have focused on the design of the hopper, including the use of various sizes of outlet holes and the addition of cyclones and other physical aids, the present invention aims to reduce the friction angle of the additive to allow faster material movement. The angle of friction refers to the phenomenon when the material gets stuck and, thus, refers to the speed at which it can fall out. By increasing the density of the additive, the friction angle is reduced, allowing the same amount of material to be added to the drilling fluid for a significantly shorter time.

Tablets can be made in various shapes and sizes. The preferred tablet size depends on the particular application, for example, on the diameter of the outlet of the hopper, on the materials used to form the tablets and on the possibility of sticking in the specific shape and size of the tablets. Tablets can be made in the form of very small dense granules and dense flakes and in the form of tablets with a diameter of up to several inches. Preferred are tablets with a diameter in the range of 3.175-19.05 mm and a length of 3.175-25.4 mm. In accordance with the present invention, any device suitable for pushing material through openings can be used. A preferred embodiment includes a belt driven mill for producing tablets, for example, the Ace Pellet mill model, commercially available from Koppers (Mansi, PA, USA). A traditional tablet mill includes a screw that pushes material into a conditioning chamber. Steam may be injected into the power chamber or the conditioning chamber, if necessary. A system of shafts push material through a die at the end of the conditioning chamber. The performance is partly dependent on the size of the holes in the tablet die. The force generated by such a tablet mill is usually sufficient to achieve maximum or optimal compressibility of the crushed material. In addition, the heat generated by friction is usually sufficient to release oils or binders from these materials containing such components without additional heating. Other methods of pressing the crushed material may also be used. Similarly, the present invention encompasses methods in which grinding and pressing processes can be performed in one device.

A material for controlling the absorption or leakage of a drilling fluid suitable for use in accordance with the present invention includes any untreated material that acts as an additive and / or a substance for controlling the absorption or leakage of a drilling fluid. At least one of the materials for controlling the absorption or leakage of the drilling fluid must be compressible to a certain extent, so that a tablet formed from such a material is denser than the material for controlling the absorption or leakage of the drilling fluid before pressing. Some organic materials suitable as a material for controlling the absorption or leakage of a drilling fluid in accordance with the present invention include cellulosic materials, for example, chopped wood, pine bark, squeezes, or pulp from fruits and / or vegetables, yellow pine, corn cobs , peanut husks, which are also carriers of insecticides, pecans, almonds, corn cobs, bee wings, cotton weeds, oat husks, rice husks. Other organic materials include the following: husk of sunflower seeds, sunflower, flax, flaxseed, cocoa beans, feather, peat moss, jute, mohair, wool, sugarcane, bagasse, sawdust, bamboo, cork tree bark, popcorn, tapioca ( cassava flour) and sorghum grain. Many mixed organic materials suitable for controlling the absorption or leakage of a drilling fluid are also suitable for the present invention, including carrageenan gum, guar gum and other soluble resins.

Organic materials often contain natural binders, for example, lignin sulfonates, hydrolytic glucose, oils or other binders, when the materials for controlling the absorption or leakage of the drilling fluid are in an untreated state and these natural substances act as binders in the additive. Most organic materials suitable as additives for the manufacture of dense additives are subjected to friction during the grinding process. This crushed material is then subjected to pressure, through which it squeezes the material with its oil through small openings to form tablets. The pressing process leads to the release of heat, which, in turn, melts the oils and other easily liquefied components of the material. These oils and other substances hold the material together so that it remains in tablet form. When only inorganic substances are used or when insufficient oil is present to hold the tablets together, oil or another binder can be added to the materials to control the care or leakage of the drilling fluid. Similarly, in cases where the oil contained in the material has a higher melting point, additional heat may be reported.

A tablet may be formed from one or more additives effective as materials for controlling the absorption or leakage of a drilling fluid. In addition, the step of applying friction to produce finely ground material can result in materials of various sizes, so that the pores of the transmission structure are effectively rammed without detrimental effects. Thus, the distribution of particles in the drilling fluid resulting from the use of a tablet according to the invention not only guarantees uniform mixing of the additive, but also uniform mixing of the particles of the additive of different sizes, if it is desirable to have a mixture of granules of different sizes.

Among the inorganic substances suitable for use in accordance with the present invention, mineral components, for example, calcium carbonate, mica, diatomaceous earth, fuller’s earth and other silicates, activated carbon, bauxite, aluminum gel, graphite, gilsonite, etc., are quite accessible. Such materials are often supplied in fibrous or powder form. Carbonate can be used alone or in combination with other desired additives. The effect of adding carbonate to organic additives is to improve solubility in an acidic environment. It also leads to tablets with increased density. Plastics are also suitable.

A significant increase in the density of materials is observed to control the absorption or leakage of the drilling fluid suitable for use in accordance with the present invention when processed into dense additives. A typical example includes a cellulosic additive with a density of 0.160 g / cm ³ (10 lb / cubic foot). When tabletting this additive with mica, the resulting density is about 0.272 g / cm 2 (17 lb / cubic foot). A significantly higher density is defined as a nontrivial increase in density compared to the density of the raw materials used to obtain a denser additive. Thus, although the addition of a component such as mica leads to an increase in the density of the raw material mixture, compression into a tablet significantly increases the density of the mixture. The increase in density directly relates to the size and shape of the particles that are pressed, and to the nature of the material. Thus, for example, increasing the density from 0.160 to 0.176 g / cm ³ (from 10 to 11 lb / cubic foot) of a particular material can be a significant increase in density, providing a faster flow of material from the hopper with reduced dust emission. Preferred materials suitable for use according to the invention include those that have a low density and have good compressibility. In addition to the advantages listed above regarding injection rate, materials with such a low density can be compressed to a large extent, resulting in a product that requires significantly less storage space. For example, corn cobs can be compressed into tablets of approximately double density compared to crushed corn cobs.

From the foregoing, it follows that the present invention can be easily adapted to use all types of waste and objects mentioned above, and that it has other obvious advantages that are inherent in the method and structure.

It should be borne in mind that some of the distinguishing features and combinations are useful and can be used without reference to other distinctive features and combinations. This is intended and is within the scope of the present claims.

Since many possible embodiments according to the invention can be carried out without departing from its scope, it should be borne in mind that all considerations put forward here or shown in the accompanying drawings should be interpreted as having illustrative but not limiting meaning. For example, a dense additive may also contain insecticides, biocides or other biologically active substances intended to reduce susceptibility to various types of decomposition or to repel pests. Although one of the advantages of the present invention is the use of agricultural by-products as materials for controlling the absorption or leakage of the drilling fluid, which minimizes the number of objects that would otherwise become waste, some agricultural products and other materials for suitable for use in accordance with the present invention, to control the absorption or leakage of the drilling fluid, are supplied in shredded water. e. A method of preparing a dense additive from such accumulations of materials to control the absorption or leakage of a drilling fluid includes producing ground material to control the absorption or leakage of a drilling fluid. Obtaining the material in a crushed form as opposed to grinding the material is also provided by the present invention.

Claims (17)

1. Tablet dense additive to control the absorption, filtration and leakage of the drilling fluid and control oiliness, viscosity and rheology during drilling operations, containing particles of crushed untreated basic material that forms the original basic material of the rock, pressed and formed into a tablet having a significantly higher density in Compared to the density of ground raw material that is dispersed in the drilling fluid directly when introduced into the drilling fluid happening to slow leakage and filtration of drilling fluid. 2. The tablet dense additive according to claim 1, wherein the base material is an organic substance. 3. The tabletted dense additive of claim 2, wherein the base material is a cellulosic material. 4. The tabletted dense supplement according to claim 1, wherein the main material is selected from the group consisting of shredded wood, pine bark, fruit squeezed, squeezed vegetables, yellow pine, corn cobs, peanut husks, pecan peel, almond shells, corn ears , bee wings, cotton weeds, kenaf, sillage, oat husk, rice husk, sunflower husk, sunflower, flax, flaxseed, cocoa beans, feather, peat moss, jute, mohair, wool, paper, sugarcane, cake sawdust, bamboo, cork bark Wood, popcorn, tapioca and sorghum grain, and combinations thereof. 5. The tablet dense additive according to claim 1, in which the base material is a mixture of two or more basic materials, one of which is an organic substance. 6. The tabletted dense additive according to claim 1, wherein the tablets have a diameter of substantially 3.175-19.05 mm and a length of substantially 3.175-25.4 mm. 7. The tabletted dense additive according to claim 1, wherein the particles of crushed raw material determine the distribution of the initial particle sizes and the tablet is able to return to essentially the distribution of the initial particle sizes of the crushed raw material so that when the tablet is dispersed in the drilling fluid, the dispersed tablet is mixed with drilling fluid. 8. The tabletted dense additive according to claim 1, which has a density exceeding 2–3 times the density of the unprocessed ground material. 9. A method of preparing a dense additive according to claim 1 for use as an additive to a drilling fluid during drilling operations of an underground formation, comprising the following steps: grinding the main rock material to produce granules, said material containing natural binders; heating granules to liquefy natural binders; pushing heated granules through openings for forming tablets with a significantly higher density than the density of the base material, and capable of dispersing in the drilling fluid directly upon contact with it. 10. The method according to claim 9, in which organic matter is used as the main material. 11. The method according to claim 9, in which the granules further have a distribution of the initial particle sizes so that the tablets return to essentially the distribution of the original particle sizes when dispersed in the drilling fluid. 12. The method according to claim 9, in which the tablets are obtained having a diameter essentially in the range of 3.175-19.05 mm and a length essentially in the range of 3.175-25.4 mm. 13. The method according to claim 9, in which receive tablets having a density exceeding 2-3 times the density of the crushed raw material. 14. The method according to claim 9, in which the main material of the breed contains crushed wood. 15. The method according to claim 9, in which the main material of the breed contains corn cob. 16. The method according to claim 9, in which the main material of the breed contains an almond shell. 17. The method according to claim 9, in which the main material of the breed contains rice husk.