CASING, PROCESS OF FORMATION OF CASING IN BOREHOLES BY ADDITIVE METHOD AND DEVICE FOR ITS FORMATION

Abstract

The invention lies in the gradual treatment of rocks vapours in a mixture of carrier and cooling gases and their gradual applying in layers which are forming a casing on walls of a borehole. The invention includes the adjustments of various quantities and types of additives in the layers and the additive method applied materials by their autonomous self-cooling without the need for external coolant by heat exchange between materials in various layers, where it forms the casing on the walls of the borehole. It describes functional parts and their interconnection: arrangement of cooling parts, separators, accelerating and mixing elements, mechanisms for their adjustments which allow forming the casing on the walls of the borehole with the possibility to influence the resulting characteristics of the casing according to demands and functional requirements in the place of the borehole.

Description

RELATED APPLICATIONS

This application is a continuation-in-part of International Patent Application No. PCT/SK2013/050008, filed Oct. 22, 2013, which is hereby incorporated by reference in its entirety, and which claims priority to Slovakian application No. PP50048-2012, filed Oct. 24, 2012.

TECHNICAL FIELD

The invention relates to a casing, a process of formation of a casing by additive method, especially in contactless thermal drilling of boreholes in geological formations and a system for its performing.

BACKGROUND ART

For strength and resistance of borehole walls, the high-quality casing is essential condition for technological use of the borehole during its excavation as well as its durability.

The issue of parallel formation of the casing and drilling process has proceeded through several stages of development. Experiments have been made to solve the issue of narrowing the borehole profile as well as the casing (tapering) by solutions such as expansion of the embedded casing profiles and also by methods of passive insertion of casing during the drilling. Among the first conceptions of casing drilling was the patent U.S. Pat. No. 3,661,218. That patent protects a method of casing drilling, but maintains the deficiencies of the rotating drill string of conventional mechanical drilling columns, namely decrescent cross-section.

Solutions which can be considered useful and were designed and put into practical use are the principles of drilling with the casing. Analysis of this technology is described in detail in R. Tessari Atall: “Drilling with casing promises major benefits” in Oil & Gas Journal Vol 97, No. 20 1999 and the article of authors Okeke et al. “Current Trends and Future Development in Casing Drilling”. In patent literature the casing drilling, as an example among others, is the object of a patent of company Tesco U.S. Pat. No. 6,705,413. The company Halliburton has a patent for drilling with a casing for directional drilling in the patent U.S. Pat. No. 6,877,570. Both mentioned patents have the main common deficiency that the rotating casing may be threatened by collapse of unstable rock from outside and thus by the complete discontinuation of the drilling process. The second common deficiency is that the rotating casing is uncementable during the whole drilling process or it is cementable in parts, and the narrowing casing must also be used for the next section.

Utilization of thermal, especially plasma, technologies in formation of a casing is the closest issue to the present invention. These solutions can be divided into two categories. The first includes solutions based on the so-called penetrators i.e. devices, a tip of which heated to the temperature above the melting point of the rock is depressed into the rock, in which it forms a melting vitrified layer and removes the excess material. The second category includes solutions based on plasma thermal flux /torch/, which melts the rock at the bottom and on the walls of the borehole at its exit from the bottom of the borehole.

The example of the first group of solutions is the patent U.S. Pat. No. 3,693,731 “Method and apparatus for tunnelling by melting” by D. Armstrong E. et al., which describes a conical penetrator, which depresses the melt into the pores of the surrounding rock and thus it forms a partially vitrified casing. A large amount of energy is required to achieve acceptable efficiency of the process and speed of penetration.

The line of direct action of heat flux of plasma flow to rock completes the solution of the patent U.S. Pat. No. 8,235,140 by Wideman T. W. et al. using the mode of so-called spallation, which is energetically preferable. It forms a disturbed layer which may be impregnated and thus it can form a temporary casing. However, the casing formed in this way shows insufficient strength.

The patent U.S. Pat. No. 6,591,920 by Foppe W. uses a molten metal supplied from the surface and heated to a temperature high above the melting point as drilling thermal medium. It depresses the melt into cracks in the rock and thereby forms a casing. But the whole process is considerably technologically difficult. The patent U.S. Pat. No. 6,851,488 by Samih Batarseh describes the formation of a casing by heat radiation flux of laser radiation, which forms a rock melt. It uses compressed air to hold the melt on the wall, and the entire borehole is filled with air as well.

The present invention eliminates the deficiencies of the above mentioned patents in forming of a casing and in the field of efficiency, material and temporal parameters and in particular functionality of casing being formed such as forming of pipe in the casing, sandwich and composite structure of the casing and thereby it surpasses them.

The above-mentioned U.S. Pat. No. 6,851,488 of Samih Batarseh: “Laser liner creation apparatus and method”, discloses the process (method) and apparatus of creation of the borehole liner by melting the surrounding rock and the cooling and perforating the rock by fluid flow through nozzles. This is the basic difference to the present invention which is based on additive layering of the processed material of the rock and additives to create homogenous layer with the composite composition, and with controllable properties and high strength given by additives.

The U.S. Pat. No. 6,851,488 belongs to the “penetrator” category which has substantial drawbacks:

• • a) the resulting structure is influenced by non-homogenous rock, by existing fracks etc., gives no guarantee of quality of the created liner with low strength parameters, the melted rock under the gravitation influence is flowing down and deformed until the cooling fluid flow is applied,
  • b) it does not solve the vital problem of the transporting simultaneously with the liner creation, and
  • c) the penetrator concept is generally failed on wrong assumption that the excessive melted rock is pushed into the surrounding rocks fracks. This is the lethal drawback in the referenced patent U.S. Pat. No. 6,851,488.
    The present invention solves these problems in principal way and has the liner composition under full control by additive process as it is solving the transport of melted/evaporated material to the surface.

The patents U.S. Pat. No. 3,907,044 and U.S. Pat. No. 5,735,355 are of penetrator melting category and are not relevant to the additive layering concept of this invention.

DISCLOSURE OF INVENTION

The mentioned deficiencies are to the great extent eliminated by a casing, a process of formation of the casing by additive method especially in thermal drilling of boreholes in geological formations, and devices for its formation according to the present invention. The casing determines and ensures a workspace of a borehole by its functions. It forms an integral part of the functioning borehole and its operation. The nature of the present invention consists in that the casing is formed by layering material from vaporized rocks by condensation and solidification on borehole walls. The casing is applied directly onto the walls of the borehole and over conventional sheeting, which sheeting is inserted into the borehole and does not need to meet very high requirements, as it is put on it mainly because of installation and handling. In formation of the casing, the material of the vaporized rock and thermal energy inserted into it are used so that by a heat treatment a mixture of rock vapours passes through phase transformations, namely to a liquid phase and a partially solid phase, and mechanical treatments and transport of the rock material from a source of generation of hot gas mixtures, namely mixtures of rock vapours and coolant vapours, to an area of formation of the casing by directing and application of the treated rock material in the area of the casing formation to the borehole wall or to the underlying layers of the casing being formed. The layered casing is formed by cooling the rock material, wherein the casing layers formation is continuous. The advantage of the additive method of casing formation lies in application of the casing alone, which, unlike impressing—penetration—mechanisms, allows to create boreholes with casing having characteristics similar to those of structural embodiments of boreholes designed today.

In thermal drilling, the main advantage over conventional drilling technologies is the possibility to form the casing directly from disintegrated material. The object of the present invention is formation of the casing by additive process from melted and vaporized rock material applied in the layers to the borehole walls, by which the casing achieves required characteristics, such as tensile strength, compressive strength, compliance, permeability, porosity, thermal insulation properties and others.

Rocks material meltdown and vaporization occur especially in thermal drilling of boreholes, where from them and from coolant transported to the place of drilling are generated the hot gas mixtures consisting of rock vapours and coolant, where cooling gases are formed by its vaporization, wherein by taking over the carrying function, also carrier gases are subsequently used for formation of the casing by additive method in the process of formation of the casing according to the present invention.

The heat treatment is a cooling, in which the generated hot gas mixtures are cooled by coolant. A phase transition of a rock vapours occurs by their cooling and by condensation liquid particles of rock and by solidification solid particles of rock are formed in the flowing mixture of rock material and cooling gases.

The generated hot gas mixtures of rock vapours and cooling gases are divided by mechanical treatment into at least two main streams. At least one stream is a stream of cold materials and at least one stream is a stream of hot materials.

Since not the entire material from melted and vaporized rocks is necessary for formation of the casing, it is necessary to separate the excess part of this material together with the cooling gases from the part which will be used for formation of the casing. Therefore at least from one of these main streams other sidestreams are further continually diverging, by which excess mixtures of rock materials and cooling gases are led away to the waste. The part of the rock material from which the casing will be formed remains in the streams of cold and hot materials.

At least one stream of hot materials and at least one stream of cold materials are formed by heat treatments which is a multistage cooling of rock materials by controlled heat transformation, wherein at least two main streams are cooled to different temperature so that the stream of cold rock materials is cooled to the temperature at which gas rock material is transformed into the solid phase and solidifying rock particles are formed, which solidify before their application as the casing layer, and the stream of hot rock materials is cooled above the temperature of the rock melting, which allows them to be mixed with cold materials and thus to form the continuous casing layer, in which layers during the heat exchange between particles occur temperature decrease of entire layer, phase transformation and thus formation of continuous casing layer. Temperature of particles in the stream of cold materials and in the stream of hot materials is different before application of the casing layer.

Waste gases, which are excess parts of cooling gases, are led away to the waste from main streams of materials by further mechanical treatments, namely by separation, and thus the streams of solidifying rock particles formed by cooling the mixtures of hot rock vapours and cooling gases, which are at the same time the carrier gases, are concentrated.

Discharge of waste cooling gases is necessary also because the coolant is continuously added as cooling and as protective and separating layer between all contact areas of the device and the mixture of hot flowing gases. Since during the process of drilling and also for the process of the casing formation it is constantly necessary to supply coolant, it is also constantly necessary to separate excess parts of cooling gases from main streams of materials and to discharge them into the waste. The concentration of mixtures of main streams, which already contain solidifying parts formed by cooling the hot rock vapours mixtures in the stream of cooling gases, is accomplished by discharge of the excess parts of cooling gases.

Cooling gases are formed by vaporization of supplied coolant and cooling gases also take over the carrying function, since they simultaneously carry rock particles, which solidify in the system, and therefore they are also carrier gases. Removed heat and temperature decrease of the resulting mixture is performed by phase transformation of the coolant, mixing the parts of the mixture and expansion of the mixtures of vaporized rock and cooling gases.

After dividing and separating the mixtures of excess rocks material and cooling gases, the streams of the mixtures of rock material and cooling gases are divided into smaller streams by mechanical treatment, namely by division into n number of channels, for the purpose of their additional treatment.

The step of separation of the excess parts of cooling gases is followed by further mechanical treatment, namely increasing the speed of cold and hot rock particles before mixing them, which is performed to accelerate and direct them.

The coolant also provides thermal protection to the device so that the coolant is continuously added as a cooling and also protective and separating layer between all contact areas of the device and the mixture of hot flowing gases.

Mixing of cold particles and hot particles occurs by connecting the stream of cold materials with the stream of hot materials, and the mixture of rocks material is formed, which is at first applied to the borehole wall and subsequently additional layers are applied on the underlying layers of the moulded casing.

The formed casing layer solidifies especially during further heat treatment, which is self-cooling, wherein internal heat transfer occurs in the applied layer, namely by heat exchange between applied hot and cold particles of the rock material in the casing layer. In the area of casing formation, a moulding device is embedded, by sliding of which an aperture is formed in the solidifying casing, which forms pipe channels in the layered casing along the borehole. A medium supply such as a coolant pipeline, an electricity conductor, a signal conductor and others, is conveyed to the slid moulding device.

Mixing of cold and hot rock particles is performed by action of opposing centrifugal forces, which empty into a common area in a channel of formation of casing layers leading into the area of application of casing layers.

Cooling of the formed casing must be controlled, wherein the formed casing layers are tempered and cooled. Hot waste gases, alternatively cooled by addition of cooling gases, are preferably used for controlled cooling of the casing.

Cooling and condensation of discharged waste rock material provide cooling of cooling gases and excess rock material to the temperature in the range of 100-250° C.

By sliding of one or several moulding devices in the solidifying casing, an aperture is formed, which shapes the pipe channel in the layered casing along the borehole, where a medium supply, in particular a coolant pipeline, an electricity conductor, a signal conductor and others, is conveyed to the slid moulding device. Connected medium supplies, which are led by the formed aperture from the surface of the borehole, are also slid by sliding of the moulding device.

In order to improve the properties of the casing, it is advantageous to add specialized additives to the flowing mixture, which comprise:

• • a. an increased supply of coolant for controlling the cooling of the mixture of rock vapours and cooling gases in order to form expansion joints in the casing using controlled cooling of applied material; and/or
  • b. reinforcement elements in order to improve the mechanical properties of the casing;

and/or

• • c. a foaming additive in order to adjust thermal-insulating and mechanical properties of the walls of the casing.
    Addition of particular additives is preferably performed before mechanical treatment of increasing the speed of cold and hot parts, and especially before mixing them in the process of acceleration of particles, namely by addition of additives to various sub-groups of n number of channels and thus materials are formed, which after application form one or more coaxial structures with the same or different characteristics, and thereby a sandwich and composite structure is formed in the casing.

The resulting casing consists of several layers, wherein some of the layers contain a certain quantitative volume of additives (up to ratio 100%), and with regard to the type and amount of the added additives, not only are the properties adjusted reciprocally among individual applied casing layers, but also properties of differing concentric parts of the formed casing can be adjusted, and thereby they form sandwich and composite aggregations and thus adjust properties of the entire casing.

A device for performing the process of formation of the casing by additive method, especially in thermal drilling of the boreholes in geological formations according to present invention, comprises the following technological parts:

• • a hot rock vapours mixture formation module;
  • mechanical treatments modules;
  • heat treatments modules;
  • transport modules;
  • directing and application block.

A hot rock vapours mixture formation and cooling gases module is a high-temperature energy flow, which produces the vaporized rock forming hot rock vapours mixed with cooling gases entering into the casing formation.

The mechanical treatments module includes:

• • a mechanical division and separation block;
  • a separation and concentration block;
  • particles division and acceleration blocks;
  • a system for mixing the particles;
  • an output streams separator.

The heat treatments module includes:

• • a cooling system;
  • a controlled cooling block.

The hot gases mixture cooling system is a group of channels, in which the hot mixture is cooled by the coolant in order to change the phase by cooling. By cooling, both liquid and solid particles of rock are formed in the flowing mixture. The group of channels of the cooling system is also designed for protection of walls of active and exposed parts of the device.

The block for directing the application includes a casing layers formation channel. This channel is a mixing slot, where solid and liquid particles of the flowing mixture are applied on the wall by kinetic energy and then they are deposited as the casing layers. After application, the hot particles in the layer are cooled autonomously, without the need for external cooling, with heat interchange between the hot and cold deposited fractions. And the casing layers formation channel is designed for discharge of cooling gases and excess particles of rock into the waste as well.

The mechanical division and separation block consists of a system of branching channels and separators separating volumes of the mixture of rock materials and cooling gases into the other blocks, as necessary.

Additional functions mechanisms may be controlled dispensers for adding the additive and these dispensers may be:

• • a. a dispenser of coolant for cooling the hot and cold material for separation/disruption of the formed casing by the expansion joint, and/or
  • b. dispensers of reinforcing concrete elements for improving the mechanical properties, and/or
  • c. dispensers of foaming additives for improving and treatment of thermal-insulation and mechanical properties of the casing walls.

The device comprises also a system of channels for additives dosage control into sub-groups of n number of channels in particles division and acceleration block, where it generates several treated streams of materials. These streams of materials form coaxial sandwich and composite structures of the casing not only along the layers which are layered in the casing, but also in radial direction relative to the axis of the borehole.

The separation and concentration of the mixtures of rock particles and gases block is a group of separators, by which division, separation and discharge of the cooling gases is performed in the guide channels, where the cooling gases are separated and the mixtures of rock particles and gases are concentrated to the desired concentrations.

The particles acceleration blocks are accelerating centrifugal devices increasing the kinetic energy of particles.

The system for mixing the particles of hot and cold streams from directing and accelerating part is a flow mixer of flowing cold and hot materials into the casing formation channel, wherein the particles are in the step of directing and acceleration directed and applied in the casing layer in the casing formation channel.

The device also preferably comprises a block of sliding forms of pipelines in the casing, which is a system of forming members, which are designed for formation of the pipe channel in the layered part of the casing along the borehole.

The output streams separator is a separator at the outlet of the casing formation channel, which separates excess materials discharged out of the casing formation channel and parts of the hot gases for tempering the casing by controlled cooling.

The controlled casing cooling block is a tempering and cooling system at an interface of the casing and the device.

The device also comprises a waste outlet, by which the collecting and cooling device discharges all excess rocks and cooling gases materials, which are cooled to the temperature below the temperature of the device resistance.

The system for mixing the particles consists of two systems of centrifugal channels, which are orientated against each other, wherein they may together form an obtuse angle, and they lead into the common area in the casing layers formation channel.

The hot mixture formation block may preferably have an annular shape of cross-section similar to the casing being formed; thereby it allows performing standard mechanical drilling or core drilling in the central area of the annular casing formation.

The present invention has the following advantages when compared to the prior art:

The present technology uses the disintegrated rock material itself and the energy inputted in them in eroding to form the casing. Due to the casing formed according to this invention, the borehole is stabilized and protected against invasive action of materials from geological action of surroundings. By formation of the composite and laminated casing, the mechanical properties of the borehole are structurally improved. The casing of the walls is corrosion resistant and from this point of view it has longer lifetime. The logistical procedures of conventional technology are eliminated, thus reducing time demands and financial burdens of the deep boreholes formation.

DESCRIPTION OF DRAWINGS

FIG. 1 shows a technological scheme of casing formation.

FIG. 2 shows a scheme of the mechanisms of casing formation by additive method.

FIG. 3 shows a cross section of the borehole as the base for foaming annular casing and pipes for distribution of media and supply of energy.

FIG. 4 shows a flow of cold and hot materials and their mixing in the casing layers formation channel.

FIG. 5 shows conical pipe formation.

FIG. 6 shows a layered formation of the casing by different functional parts in the radial direction.

EXAMPLE OF THE EMBODIMENT

The formation of the casing from the disintegrated rock 18 according to this invention is given by the sequence of treatment processes and coating of the rock vapour materials in the casing layers, by their autonomous cooling, when the casing is formed on the walls of the borehole 17. The casing is formed from applied layers of materials having different properties. The layers of materials with different properties are formed by sandwich-composite structures of preferred strength properties. In the process of formation, the layers undergo a controlled phase transition and are connected together. They contain the crystalline structure of the desired properties, which, in the process of their formation, were solidified in the individual layers, thereby creating the crystalline structures of the preferred strength properties. These layers comprise reinforcement materials, which were added as additives to the liquid materials, and thus reinforce the particular solidified layers and the resulting casing. The casing may include transport channels for transport of material. This occurs in the casing formation, which provides the formation of the casing especially in the thermal drilling of the boreholes 17 in geological formations of rocks 18 according to the invention, in which one preferred embodiment is described in the following steps.

The hot mixture of the rocks vapours and coolants vapours, which in certain phase of the technological process become carrier gases, with the temperature higher than the boiling point of each of the rocks fractions, enters the input part of the device for casing formation by additive method, i.e. the hot mixture formation generator 1. In the block 2 of the mechanical distribution, this mixture of rocks vapours and coolant vapours is divided into two main streams. Both main streams are selectively and controllably cooled, each in its cooling block 3 to different technological temperatures. One stream is cooled so that the main and essential part of the flow is condensed and subsequently solidified particles. This stream, preferably containing 60-90 weight % relative to the weight of the vaporized material flow of the entering mixture of rock vapours and coolant vapours, is a stream of cold material. From the stream of cold material, the excess mixtures of rocks vapours and coolant vapours are discharged into the outlet channel of waste material treatment, preferably in an amount of 50-70 weight % relative to the weight of flow of vaporized material, which does not participate in the formation of the layered casing 13, prior to its further treatment. In the second flow of the mixture of rocks vapours and coolant vapours, preferably containing 10-40 weight % relative to the weight of flow of vaporized material of the entering, these mixtures are cooled so that the main and essential part of the flow are gaseous and liquid fractions, and thereby the nature of the flowing of hot material is given.

All parts of the device, which come into contact with streams of flowing gases and high temperature vapours, are necessarily protected from their thermal effects. Protection is carried out by the surface cooling of functional bodies of the device, namely by continuous addition of the coolant. Except for the mentioned protective function, the coolant also performs a technological function, wherein the controlled cooling of the mixture of gases and vapours is controlled by its amount, namely by blending it in the mixture of gases and vapours; thereby the final mixture reaches the required temperature at which it has the desired functional properties. Heat transfer between coolant being mixed and rock vapours uses the latent heat by phase transition of the coolant and the heat consumed by the expansion of the mixture of the vaporized rock and cooling gases for cooling the final mixture. Addition of the coolant is controlled and realized by the cooling block 3.

By adding further coolant to the mixture of rocks vapours and coolant vapours, the total volume of flowing mixtures is increasing and thereby their temperature is decreasing and required fractions for further processing are being formed. The flowing mixture consists of technological fractions, i.e. of the rock material in a gas and/or liquid and/or solid phase, and of refrigerants. Excess cooling gases, which fulfil also the function of the carrier gases, are separated in the separation block 5 and discharged into the outlet channel for waste material. The concentrated stream of gases and solidifying particles of rock continues to the area, where additives of reinforcing elements and/or foaming reagent in the line of cold materials are added or the hot concentrated mixture is cooled in order to form expansion joints by controlled cooling in the lines of cold materials and hot materials. Injection of additives is provided by mechanisms 4 of additional functions.

In both streams, namely in the stream of cold materials and in the stream of hot materials in particles distribution and acceleration block 6 streams of mixtures are divided into three groups of channels, and in the first group are 6 pairs of channels, in the second group are 6 pairs of channels, and in the third group are 12 pairs of channels. These groups of channels are arranged so that they cover the whole surface of the casing width. The pairs of channels refer to two channels connecting two streams into one. One channel is for cold material and the other channel is for hot material. Into the groups of channels, various additives are added, and thereby different mixtures of materials are formed and these flow in the appropriate groups of channels. In the first group, the material is treated so that the additives of reinforcement elements are added. The material modified in this way is further divided into 6 pairs of channels. In the second group, the material is not modified by adding additives. The material modified in this way is further divided into 6 pairs of channels. In the third group, the material is modified so that the foaming additives are added. The material modified in this way is further divided into 12 pairs of channels. Streams of mixtures of rocks vapours and coolant vapours are then accelerated to increase their kinetic energy. Increasing the speed of the particles is performed for the purpose of acceleration and direction, especially in the direction of the normal to the layers of the casing by inputting the kinetic energy into the cold particles and hot particles in the accelerating sections before entering into the block 9 of directing the application from which the mixed stream is applied to the surface of the walls, thereby forming the casing itself. Outlets of the channels of cold materials and hot materials of the streams are situated alternately in the system 7 for mixing parts of rocks and carrier gases, wherein the mixing of hot and cold material occurs by the outflow from each of these channels, wherein solid and liquid fractions are applied perpendicularly to the wall of the casing (FIG. 3). Different properties of materials flowing from different groups of channels allow to apply mixtures with different concentrations of cold particles, hot particles and additives, and thereby the applied layer (FIG. 6) forms the sandwich and composite arrangement with advantageous properties of the casing not only by modification of the properties of the applied layers over time, but also by applying different materials from the groups of channels in the direction of the axis of the applied casing.

Materials flowing against each other are mixed by the effect of the centrifugal forces and form a layered casing 13 applied to the wall or subsequently to the underlying, already applied casing layer 14, wherein they solidify by self-cooling during heat transfer in the applied layer between deposited hot, liquid and cold particles of the intermingled streams of cold materials and hot materials in the applied casing layer 14. Each new layer of the layered casing 13 of applied material is thrown from the block 9 for directing and application from the nozzles to the surface, and then diagonally across the surface of the conical area onto the already cooled layers of the applied casing 14, wherein different properties of various tubular parts of the final applied casing 14 are achieved by application of various and variously mixed mixtures with a differing content of additives being admixed by a system 7 for mixing the parts of rocks and carrier gases, which empties into the block 9 for directing the application.

Cooling gases and residues of non-applied rock particles are lead away along the casing being formed into an exit block 12 for waste products treatment. The casing is temperated by controlled cooling of the waste mixtures using the hot vapours, which allows inside tensions in the formed casing to relax and to temper the casing by the separated vapours and gases of the discharged and excess material in the separator 10 of output streams, which are not involved in the formation of the casing and is lead away into the waste part of the device.

In the exit block 12 for waste products treatment, all fractions of residual/surplus material are cooled, wherein they are mixed to the final temperature of the carrier hot and cooling gases and residual rock material, most preferably in the range of 100-250° C., less preferably in the range of 200-450° C.

In the formed peripheral casing layer (FIG. 4), the pipelines are aimed by the moulding device 16. By sliding the moulding device 16 in one such a pipeline, the aperture (FIG. 5) is being formed in the solidified casing in the direction of the casing formation, which forms the pipe channel along the borehole 17. To the body of the shifted moulding device 16 of the piping formation block 8 the supply 15 of a medium, such as water, conductor of electricity, signal cables and others, is connected.

The sequence of preparation and formation of the casing is shown schematically in the FIG. 1.

LIST OF REFERENCE SIGNS

• 1. A hot mixture formation generator
• 2. A mechanical division block
• 3. A cooling block
• 4. Additional functions mechanisms
• 5. A separation block
• 6. Distribution and acceleration of particles blocks
• 7. A system for mixing parts of rocks and carrier gases
• 8. A pipeline forming block
• 9. A block for directing the application
• 10. An output streams separator
• 11. A casing controlled cooling block
• 12. An exit block for waste products treatment
• 13. A layered casing
• 14. An applied layer of a casing
• 15. Media supplies
• 16. A moulding device
• 17. A borehole drilled by conventional or other technology
• 18. A rock

Claims

1. A casing designated for reinforcement and/or sealing of borehole walls characterized in that the casing comprises at least one layer of a material applied to a rock, or to a previous layer of the casing, wherein the at least one layer comprises solidified bonded added materials of rocks and additive particles, thus forming a layer of preferred strength properties.

2. The casing according to claim 1 characterized in that the additives are reinforcing elements and/or foaming additives.

3. The casing according to claim 1 characterized in that the casing is multi-layered, and layered structures of different properties are formed because of the content of the additives in each layer and layered structures thereby preferably achieve properties of composites.

4. A process of formation of the casing according to claim 1 in boreholes in additive method namely in thermal drilling in geological formations, characterized in that a vaporized rock and thermal energy inserted into said vaporized rock are used for formation of the casing so that a mixture of rock vapours is thermally and mechanically treated, wherein:

a thermal treatment is cooling by a coolant during which a phase transition occurs and, by condensation, liquid particles of rock are formed, and, by solidification, solid particles of rock are formed in a flowing mixture of gaseous, liquid, and solid particles of rocks and cooling gases,

by mechanical treatments, the generated hot gas mixtures of the rock vapors and vaporized coolant are divided into at least two main streams, of which at least one stream is a stream of cold materials and at least one stream is a stream of hot materials, and at least one of these streams is further branching into further sidestreams, by which excess mixtures of rock materials and cooling gases are exhausted into the waste, wherein the stream of cold materials is cooled to the temperature at which the gaseous material of the rocks is transformed into the solid phase and solidifying particles of rocks are formed, the solidifying particles of rocks solidify before their application as a layer of the casing, and the stream of hot materials is cooled to the temperature which is above the melting temperature of rocks and the stream of hot materials, after mixing with the cold materials, forms a mixture that is cooled below the solidification point of rocks and thus it forms a solid continuous casing layer,

transport of the rock material from a source of generation of hot gas mixtures, namely mixtures of rock vapours and coolant vapours to an area of formation of the casing by directing and application of the treated rock material in the area of formation of the casing to the borehole wall or to the underlying layers of the casing being formed and by cooling the rock material, the layered casing is formed, wherein the formation of casing layers is continuous.

5. The process of formation of the casing according to claim 4 characterized in that only a part of the rock materials from which the casing will be formed remains in the stream of cold and hot materials.

6. The process of formation of the casing according to claim 4 characterized in that at least one stream of hot materials and at least one stream of cold materials are formed by heat treatments which is a multistage cooling of rock materials by controlled heat transformation.

7. The process of formation of the casing according to claim 4 characterized in that, waste gases, which are excess parts of cooling gases, are exhausted to the waste from main streams by further mechanical treatments, namely by separation, and thus the streams of solidifying rock particles formed by cooling the mixtures of hot rock vapours and cooling gases, which are at the same time the carrier gases, are concentrated.

8. The process of formation of the casing according to claim 4 characterized in that one of the heat treatment method is a cooling by expansion of mixtures of vaporized rock and cooling gases.

9. The process of formation of the casing according to claim 4 characterized in that after dividing and separating the excess mixtures and cooling gases, the streams of the mixtures of rock material and cooling gases are divided by mechanical treatment into smaller streams for the purpose of their different treatment, and each of these smaller streams is further divided into other smaller streams.

10. The process of formation of the casing according to claim 4 characterized in that the step of separation of the excess parts of cooling gases is followed by further mechanical treatment, namely increasing of speed of cold and hot rock particles before mixing them, which is performed in order to accelerate and direct them.

11. The process of formation of the casing according to claim 4 characterized in that the coolant also provides thermal protection to the device so, that the coolant is continuously added as a cooling and also protective and separating layer between all contact areas of the device and the mixture of hot flowing gases.

12. The process of formation of the casing according to claim 4 characterized in that by further mechanical treatment, namely by mixing of cold rock particles and hot rock particles, a mixture of rock material is formed, which is applied to the borehole wall, wherein it forms the first casing layer, and then the further casing layers are aimed so that the mixture of rock material is applied onto the underlying layers of the formed casing.

13. The process of formation of the casing according to claim 4 characterized in that the formed casing layer solidifies during further heat treatment, which is self-cooling, wherein internal heat transfer occurs in the applied layer, namely by heat exchange between applied hot and cold particles of the rock material in the casing layer.

14. The process of formation of the casing according to claim 4 characterized in that in the area of casing formation, a moulding device is embedded, by sliding of which an aperture is formed in the solidifying casing, which forms pipe channels in the layered casing along the borehole, where a medium supply such as a coolant pipeline, an electricity conductor, a signal conductor and others, is conveyed to the slid moulding device.

15. The process of formation of the casing according to claim 4 characterized in that mixing of cold and hot rock particles is performed by action of opposing centrifugal streams of mixtures, which empty into a common area in a channel of formation of the casing layers leading into the area of application of casing layers.

16. The process of formation of the casing according to claim 4 characterized in that cooling of the casing is controlled by further heat treatment, in which hot waste gases are used, which are controlled by mixing with the coolant so that they temper and/or cool the formed casing.

17. The process of formation of the casing according to claim 4 characterized in that cooling and condensation of discharged waste rock material provide cooling of cooling gases and excess rock material to the temperature in the range of 100-250° C.

18. The process of formation of the casing according to claim 14 characterized in that by sliding the moulding device, also connected supplies of media are slid in the formed apertures, in particular of media such as coolant pipelines, conductors of electricity, signal conductors, and others, which are led by a generated aperture to the surface of the borehole.

19. The process of formation of the casing according to claim 4 characterized in that specialized additives are added, which comprise:

a. an increased supply of coolant for controlling the cooling of the mixture of rock vapours and cooling gases in order to form expansion joints in the casing using controlled cooling of applied material; and/or

b. reinforcement elements in order to improve the mechanical properties of the casing; and/or

c. a foaming additive in order to adjust thermal-insulating and mechanical properties of the walls of the casing.

20. The process of formation of the casing according to claim 4 characterized in that addition of particular additives is performed before mechanical treatment for increasing the speed of cold and hot parts, and especially before mixing them in the process of acceleration of particles.

21. The process of formation of the casing according to claim 4, characterized in that by different treatment of streams by addition of additives into the groups of channels, different materials are formed, which are further divided and after application they form one or more coaxial structures with the same or different characteristics, and thereby a sandwich and composite structure is formed in the casing.

22. A device for performing the process of formation of the casing in additive method, namely in thermal drilling of boreholes in geological formations according to claim 4 characterized in that it comprises the following technological parts: wherein:

a hot rock vapours mixture formation module,

mechanical treatments modules,

heat treatments modules,

the hot rock vapours mixture formation module contains a high-temperature energy flow generator (1), which produces the vaporized rock and forms hot rock vapours being mixed with cooling gases entering into the casing formation;

mechanical treatments modules comprises: a mechanical division and separation block (2) for mechanical division of hot rock vapours and cooling gases and separation of hot rock vapours, which contains a separator of solid and gas rock vapours and a flow regulator of hot vapours, and consists of a group of inlet and outlet channels of the mechanical division block (2), particles division and acceleration blocks (6) for division and acceleration of hot gas vapours and additive particles, which contain a system of branching channels and separators separating volumes of the mixture of rock materials and carrier gases and each separated branch contains an accelerator at the outlet of the division and separation block (6), a system (7) for mixing the particles of hot and cold streams before application of hot gas vapours, additive particles, and cooling gases, which is formed by a system of inlet and mixing channels and directing outlet nozzles, a separator (10) of outlet streams of non-applied hot gas vapours, additive particles and carrier cooling gases, which consists of a collector of a liquid and solid parts of rocks and channels of cooled gases of rock vapours and cooling gases, which empty into a block (11) for controlled cooling of the casing;

heat treatments modules contain a cooling block (3) for cooling of hot mixture of rock vapours and cooling gases and said cooling block for cooling of the hot mixture of gases contains a channel grouping of the cooling block (3), in which the hot mixture of gas vapours is cooled by a coolant in order to achieve a phase transition, wherein, by cooling, liquid parts of the rock are formed in a flowing mixture of carrier cooling gas and rock vapours.

23. The device for performing the process of formation of the casing according to claim 22 characterized in that the cooling block (3) is a grouping of channels which forms also a system for protection of walls of active and exposed parts of the device.

24. The device for performing the process of formation of the casing according to claim 22 characterized in that it further contains mechanisms (4) of additional functions, by which dispensers for adding the additives are controlled and these dispensers may be at least:

a dispenser of coolant for cooling the hot and cold material for separations/disruptions of the formed casing by the expansion joint, and/or

dispensers of additive reinforcing materials for improving the mechanical properties, and/or

dispensers of foaming additives for improving and treatment of thermal-insulation and mechanical properties of the casing walls.

25. The device for performing the process of formation of the casing according to claim 22 characterized in that it further comprises group of channels for additives dosage control in a particles division and acceleration block (6), where it generates differently treated streams of materials, which form coaxial sandwich and composite structures of the casing, not only along the layers which are layered in the casing, but also in radial direction relative to the axis of the borehole.

26. The device for performing the process of formation of the casing according to claim 22 characterized in that the mechanical treatments module further comprises a separation and concentration of the mixtures of rock particles and gases block (5), and it is a group of separators, by which division, separation and discharge of the cooling gases is performed in the channels, where the cooling gases are separated and the mixtures of rock particles and gases are concentrated to the desired concentrations.

27. The device for performing the process of formation of the casing according to claim 22 characterized in that the particles acceleration blocks (6) are accelerating centrifugal devices increasing the kinetic energy of particles.

28. The device for performing the process of formation of the casing according to claim 22 characterized in that the system (7) for mixing the parts of the hot and cold streams from directing and accelerating part is a mixer of streams of flowing hot and cold materials into the casing formation channel, wherein the particles are in the step of directing and acceleration directed and applied in the casing layer in the casing formation channel.

29. The device for performing the process of formation of the casing according to claim 22 characterized in that it further comprises a block (8) of sliding forms of pipelines in the casing, which is a system of moulding members, which are designed for formation of the pipe channel in the layered part of the casing along the borehole.

30. The device for performing the process of formation of the casing according to claim 22 characterized in that the output streams separator (10) is a separator at the outlet of the casing formation channel, which separates excess materials discharged out of the casing formation channel and parts of the hot gases for tempering the casing by controlled cooling.

31. The device for performing the process of formation of the casing according to claim 22 characterized in that the heat treatments modules further contain a block (11) for controlled cooling of the casing, which is a tempering and cooling system at interface of the layered casing and the device.

32. The device for performing the process of formation of the casing according to claim 22 characterized in that it further comprises an outlet (12) for waste products, which contains a system of outlet channels by which the collecting and cooling device discharges all excess rocks and cooling gases materials, which are cooled to the temperature below the temperature of the device resistance.

33. The device for performing the process of formation of the casing according to claim 22 characterized in that the system (7) for mixing the particles consists of two systems of centrifugal channels, which are orientated against each other and lead into the channel of formation of casing layers application.

34. The device for performing the process of formation of the casing according to claim 22 characterized in that the hot mixture formation generator (1) has an annular shape of cross-section similar to the casing being formed and thereby it allows to perform standard mechanical drilling (17) or core drilling in the central area of the annular casing formation.