WO2008144096A1 - Method and system for particle jet boring - Google Patents

Method and system for particle jet boring Download PDF

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Publication number
WO2008144096A1
WO2008144096A1 PCT/US2008/055895 US2008055895W WO2008144096A1 WO 2008144096 A1 WO2008144096 A1 WO 2008144096A1 US 2008055895 W US2008055895 W US 2008055895W WO 2008144096 A1 WO2008144096 A1 WO 2008144096A1
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WO
WIPO (PCT)
Prior art keywords
impactors
impactor
slurry
jet head
well bore
Prior art date
Application number
PCT/US2008/055895
Other languages
English (en)
French (fr)
Inventor
Harry B. Curlett
Original Assignee
Terrawatt Holdings Corporation
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Terrawatt Holdings Corporation filed Critical Terrawatt Holdings Corporation
Priority to CN200880023970A priority Critical patent/CN101730783A/zh
Priority to CA002684587A priority patent/CA2684587A1/en
Priority to US12/599,418 priority patent/US20100307830A1/en
Priority to JP2010508466A priority patent/JP2010527418A/ja
Priority to MX2009012259A priority patent/MX2009012259A/es
Priority to EP08743686A priority patent/EP2153011A1/en
Priority to BRPI0811594-0A2A priority patent/BRPI0811594A2/pt
Priority to AU2008254460A priority patent/AU2008254460A1/en
Publication of WO2008144096A1 publication Critical patent/WO2008144096A1/en
Priority to IL202024A priority patent/IL202024A0/en

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Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B7/00Special methods or apparatus for drilling
    • E21B7/18Drilling by liquid or gas jets, with or without entrained pellets

Definitions

  • the present invention relates to the oil, gas, and geothermal drilling industries, and more particularly, but not by way of limitation, to methods and systems of particle jet boring.
  • Particle Jet Drilling has been investigated for the past approximately 45 years as a potential method to reduce the cost of drilling deep large-diameter well bores. Practical and economical application of PJD methods have been sought throughout this time as a means to increase the ROP, reduce drill-bit rotary-mechanical wear on the down-hole drilling equipment, and assist in drilling as near vertical a well bore as possible when drilling oil, gas, and/or geothermal well bores.
  • PJD system investigations have focused mainly on increasing the ROP for drilling deep large-diameter well bores.
  • This technology is best described as the use of a heterogeneous slurry comprised of solid particles entrained within a drilling fluid that is circulated into the well bore through the pipe string and accelerated through a fluid nozzle system at a distal end of the pipe string within the well bore to impact and disintegrate the subterranean formations being drilled through various energy transfer mechanisms that vary with the materials and operating conditions present.
  • the investigation of PJD methods and equipment for drilling well bores has fallen into two main categories of investigation.
  • the first category is the use of angular, relatively low-density crystalline structured abrasive particles for Abrasive Jet Drilling (AJD) investigations which eventually migrated into the second area of investigation which is the use of the relatively higher density ferrous solid material impactors for Impact Jet Drilling (IJD) purposes. While both these processes have been investigated for decades and much progress has been made after spending many millions of dollars for their investigation, the process of PJD has not been practiced commercially for drilling deep, large-diameter well bores.
  • the investigation history can be seen starting with using crystalline sand particles as the abrasive in the early AJD drilling process.
  • the AJD process migrated to the IJD process with the introduction of the relatively higher density ferrous solid particle impactors in the form of steel shot.
  • the process includes providing a fluid circuit comprising a surface drilling fluid system, a drill-pipe system within a well bore, and a drill bit or nozzle system attached to the drill string which may accelerate the drilling fluid against the well bore bottom hole, circulating the drilled cuttings and drilling fluid to the surface for separation, and processing the drilling fluid for reuse.
  • Solid impactors are added to the drilling fluid by various means to create an impactor slurry.
  • the impactor slurry is then pumped through the pipe string to the drill bit and/or nozzle system and impinged against the bottom hole formation to modify it.
  • the drilled cuttings, impactors, and drilling fluid are circulated to the surface equipment through the well bore where the drilled cuttings are separated.
  • the drilling fluid and impactors are separately processed by various means for recirculation and reuse.
  • the physics of the impactor-earthen formation modification process is one whereby the jetted impactor ' s impulse force must exceed a Critical Formation Cutting Stress (CFCS) level within the earthen formation.
  • CFCS Critical Formation Cutting Stress
  • a particle jet boring method and system is provided which substantially eliminates or reduces disadvantages and problems associated with previous systems and methods.
  • Various embodiments of the present invention contemplate boring a well bore by providing a high-pressure flow line adapted for high-pressure fluid to flow therethrough; providing an impactor injector coupled to the high-pressure flow line and adapted to accelerate a plurality of impactors and to inject the accelerated impactors into the fluid to form an impactor slurry of entrained impactors and fluid; transporting the impactor slurry to a pipe string in fluid communication with the high-pressure flow line; transporting the impactor slurry through the pipe string to a jet head connected to a distal end thereof and in fluid communication therewith; accelerating the impactor slurry in a down-hole direction and in a tangential direction to create a swirling flow of impactor slurry; impinging a formation of a well bore with the accelerated impactor slurry for removing formation particles therefrom; transporting the impactor slurry and the formation particles to an above-ground separator; separating at least a portion of the formation particles from the impactor s
  • Various embodiments may also include providing a plurality of nozzle ports disposed radially around a periphery of the jet head and adapted to allow at least a portion of the impactor slurry to flow therethrough to impinge a side of the well bore. And may further include using at least a portion of the plurality of nozzle ports to generate a vectored thrust on the jet head.
  • Various embodiments may also include monitoring a plurality of conditions including one or more of the following: a volume of impactors entrained in the impactor slurry; a size mixture of impactors entrained in the impactor slurry; a rate of penetration on the well bore formation; a density of the impactor slurry; an impactor count returning to the surface; a pressure of the impactor slurry; and a drill-string weight on bottom.
  • Various embodiments may also include modulating one or more of the plurality of conditions to modulate at least one of a well bore diameter and the rate of penetration.
  • Various embodiments may also include using a bent sub to generate an angled position of the jet head to allow directional boring.
  • the boring of a well bore may include providing a high- pressure motive fluid flow; establishing venturi flow conditions at an access port into the high- pressure motive fluid; accelerating a plurality of impactors, the plurality of impactors adapted to be entrained in the high-pressure motive fluid for creating an impactor slurry; injecting the accelerated impactors into the high-pressure motive fluid by passing the accelerated impactors through a low-pressure area created by the venturi flow conditions; transporting the impactor slurry through a pipe string to a jet head connected to a distal end thereof and in fluid communication therewith, the jet head adapted for flowing the impactor slurry therethrough; accelerating the impactor slurry flowing through the jet head for impinging a surface of a well bore therewith and removing formation particles therefrom.
  • Various embodiments may include accelerating the plurality of impactors with enough kinetic energy to prevent the venturi flow conditions from ceasing. And where at least one of a mechanical, a fluidic, and an electromotive force is used to accelerate the plurality of impactors.
  • Various embodiments may include where the venturi flow conditions are established using a dual concentric orifice adapted to generate a low-pressure region at the access port.
  • the concentric orifice is adapted to swirl the motive fluid.
  • an impeller wheel is used to accelerate the plurality of impactors.
  • Some embodiments contemplate boring a well bore by providing a supply of impactors; entraining the impactors into a fluid to form an impactor slurry; transporting the impactor slurry through a pipe string to a jet head connected to a distal end thereof and in fluid communication therewith; passing the impactor slurry through a jet head housing, the jet head housing having a stator therein adapted to impart a swirling flow regime to the impactor slurry passing therethrough; passing the impactor slurry through a swirl intensifier adapted to accelerate the impactor slurry both in an axial direction and in a tangential direction; and passing the impactor slurry through a conical shaped exit orifice adapted to centralize and stabilize the jet head while preserving a velocity of the impactor slurry flowing therefrom; and impinging a surface of a well bore to remove formation particles therefrom.
  • Various embodiments may also include modulating the impactor slurry to change a diameter of the well bore being impinged. And forming a reentrant toroidal flow regime for entraining the formation particles into the impactor slurry and adapted to further abrade the surface.
  • Some embodiments may include where the jet head housing has a converging conically shaped section at an entrance thereof for accelerating the impactor slurry flowing therethrough.
  • the jet head housing has an expanding conically shaped section at an exit thereof adapted to generate a conically-shaped impactor-slurry jet form.
  • the impactor slurry exits the jet head as a dual-jet form comprising an inner cylindrical shaped jet region and an outer flowing conical jet region, wherein a greater portion of the impactor slurry flows through the outer flowing conical jet region.
  • the impactors are solid particles on the order of .025 inches in diameter. Impactors, such as, solid particle impactors, may range in size from the largest solid particle impactor that can be processed throughout the circuit to the smallest solid particle impactor that can satisfy the minimum mass- momentum-impulse force required to exceed the minimum critical formation cutting stress force of the earthen formations being drilled. In some embodiments, the impactors impinge the well bore at a speed of at least 1 ,200 feet per second.
  • the impactors impinge the well bore at a speed sufficient to remove formation particles having a mass greater than a mass of the impactors. In some embodiments, seven grains of formation are removed for each impactor impinging the well bore. In some embodiments, the impactors impinge the well bore using a combination of shear forces, compression forces, and abrasion/erosion forces.
  • the stator has a plurality of stator vanes running axially along an exterior surface thereof and adapted to impart tangential-radial forces on the impactor slurry flowing thereby. In some embodiments, the stator is adapted to be removed from the jet head.
  • Some embodiments rotate the jet head while some do not rotate the jet head. Some embodiments utilize the jet head in conjunction with roller-cone drill bits while some use the jet head in conjunction with fixed-cutter drill bits. Some embodiments utilize impactors to modify the well bore wall to mitigate low-pressure formation-fluid losses during drilling and casing operations; to minimize formation hydration; to minimize high-pressure flow into the well bore; to minimize fluid invasion into producing formation; to increase its structural integrity; to mitigate mechanical or thermal spallation. Some embodiments utilize impactors to modify the well bore wall in combination with other methods of lost-circulation remedies. Some embodiments use impactors to work harden the surfaces of the well bore and/or form casing connections. Some embodiments may prevent or minimize spurt loss, lost circulation, and/or filter cake to minimize differential sticking.
  • Another component sub-system may be a jet head that incorporates a combination of one, some, or none of the following features including a) a fluidic amplifier for impactor acceleration dynamics; b) a jet form such that a bottom hole pattern is cut in a manner that allows the interior of the jet head to be centralized and stabilized by the jet head to produce a point-and-drill well bore that can be straight, vertical, or directional; c) a jet form that dynamically control the diameter of the well bore through modulation of the circuit to modulate the impactor slurry, impactor size, and impactor concentrations; d) perpendicular flowing jets that can be used to modify the well-bore wall while generating a neutral lateral thrust or a selectively vectored lateral thrust on the jet head; f) retrieval of the jet head's intemal-stator system via a wire line or reverse circulation slurry flow pressure in order to change the configuration; and/or g) a jet head that does not require conventional pipe
  • FIG, 1 illustrates a flow diagram of a circuit that provides an overview of some circuit components
  • FIG. 2 illustrates the physical components of an embodiment of the circuit
  • FIGS. 3a-b further illustrate an injector of FIG 2;
  • FIGS. 4a-c illustrate various formation types, a pipe string, and a jet head
  • FIGS. 5a-f illustrate various views of an embodiment of a jet head
  • FIGS. 6a-d illustrate various views of a well bore and a jet head; and [0026] FIG. 7a-d illustrate various views of a jet head.
  • FIG. 1 provides an overview of various steps practiced in boring deep large- diameter well bores according to various embodiments.
  • the process 100 begins at step 102 where impactors are supplied for the process, for example, solid material impactors such as steel shot particles.
  • the impactors are then stored within a portable impactor processing and storage system which may be in close proximity to a drilling rig.
  • the impactors are fluidized or processed through a particle injector system to produce a low volume, highly concentrated impactor slurry sufficiently pressurized to be discharged at step 108 into the high pressure drilling fluid being independently pumped by the drilling rig's slurry pumps.
  • the particle injector generates a highly concentrated, low volume, high pressure impactor slurry which may also be used to modulate the slurry concentration.
  • a description of the particle injector and its functions will be described in greater detail below.
  • the terms drill, drilling, drill pipe, drilling rig, drilling fluid, or any other use of the te ⁇ n drill is intended in its broadest sense to mean devices, apparatuses, systems, and methods related to boring a hole in general and not intended to be limited to those devices, apparatuses, systems, and methods related to mechanical drilling involving drill bits and/or rotation of drill bits,
  • the dilute impactor slurry is directed to the jet head to perform various functions.
  • the jet head may be configured in various configurations and various surface operating parameters may be changed to effect optimization of boring, well bore hole conditioning, and well bore direction and inclination functions.
  • Some embodiments of the fluidic circuit and the jet head provide for a continuous supply of the impactor slurry. A description of the jet head and its functions will be described in greater detail below.
  • the drilling, formation conditioning, and well-bore directional operational information are observed.
  • the information from step 112 is used to determine whether the jet head functions are performing optimally.
  • the observation data may come from surface command and control instrumentation and/or subsurface instrumentation for monitoring of drilling operations.
  • certain operating parameters can be changed at the surface at step 118 or the internal part, such as a stator housing, of the jet head can be retrieved by use of a wire line to bring the internal part of the jet head to the surface to physically change its configuration at step 116 and be returned to the jet head by sending the internal part back down the pipe string to be again seated in the jet head to effect optimization of the operation of the jet head at step 120 for the functions of boring, conditioning the well bore, and/or controlling the inclination and azimuth of the well bore.
  • the impactor slurry and formation cuttings are circulated to the surface equipment through the annulus region between the pipe string exterior and the interior well-bore wall.
  • the impactor slurry and formation cuttings continue to be circulated through the drilling rig's surface equipment to a point where they are separated from the fluid by a separator, such as a vibrating separator, a hydro-cyclone separator, or a magnetic separator at step 124.
  • the formation particles may be discarded.
  • the impactors are transported at step 126 then separated at step 130 from the formation cuttings by a separator.
  • each of the separations described herein may be accomplished in one separator or in a plurality of separators and may be accomplished in a variety of different orders.
  • the impactors may then be transported at step 134 to a separator where the impactors are separated at step 136 according to mass from the hydraulic transport fluid and discharged into a storage tank where the impactors can be further processed at step 138 for consistent mass and size and/or stored in the portable impactor processing and storage system impactor storage tank to be re-used in step 104.
  • the fluid separated from the impactors and formation cuttings passes into the drilling rig's fluid processing, conditioning, and storage system.
  • the processed and stored fluid is subsequently pumped in step 132 by the drilling rig ' s pumps into the drilling rig's high-pressure flow line system where the fluid is again combined with the concentrated impactor stream at step 108 to generate the impactor slurry.
  • This pressurized impactor slurry may be comprised of impactors that are both new and those that have been used, recovered, and re-injected into the high-pressure fluid for transportation to the jet head.
  • the rig's fluid processing, conditioning, and storage system 240 holds conditioned fluid 245.
  • Drilling rig pump suction line 235 is connected to both the storage tank 240 and the pump 230.
  • the stored fluid 245 is sucked into and pumped by drilling rig pump 230 into the drilling rig surface high pressure flow lines 220.
  • High pressure flow line 455 is connected to the drilling rig's high pressure flow line 220 through which the concentrated impactor discharge flow from injector 300 is combined with the drilling fluid flow generated by the drilling rig pumps 230 to form impactor slurry.
  • the impactor slurry is transported through the drilling rig's swivel 210, through the pipe string 200 which is connected to jet head 800 within the well bore 700.
  • the impactors and cuttings slurry 255 are initially circulated through the annulus region between the pipe string 200 and the well bore system 700 and subsequently in the annulus region between the pipe string 200 and progressively the well head 100, the well pressure control equipment (not shown) but illustrated by casing 110, the bell nipple 120 and finally into the flow line 130 and onto the separator 250 where the impactors and formation cuttings 255 are separated from the fluid 245.
  • the fluid 245 is processed, conditioned, and stored in the processing, conditioning and storage system 240.
  • the impactors may be formed of metal and may have magnetic properties.
  • the impactors and formation cuttings slurry 255 may be separated from the fluid 245 by the means of a separator, such as a shaker 250 and discharged onto a magnetic separator system 600.
  • the magnetic drum 610 of magnetic separation system 600 magnetically holds the impactors 335 while allowing gravity to separate the formation cuttings 259 into formation cuttings discharge pile 260.
  • the impactors 335 are subsequently released by the action of the magnetic drum 610 into an impactor collector 620 where the impactors are fed into hydraulic eductor 630 driven by a motive fluid pumped through line 465 through eductor 630 into flow line 470 to transport the recovered impactors through a hydro-cyclone separator 450 where the recovered impactors are separated from the motive fluid which is discharged into holding tank 408.
  • the separated impactors are discharged through the underflow orifice of the hydro-cyclone separator 450 into impactor storage tank 402. Fluid 245 is transferred to fluid holding tank 408 within portable impactor processing and holding tank skid assembly 400 by vertical impeller pump 505 through low pressure flow line 460.
  • Fluid 410 from tank 408 is gravity fed into the suction of impeller pump 435 and discharged into eductors 440 and 630.
  • Eductor 440 is circulated to periodically circulate the impactors in tank 402 to ensure the impactors will flow freely into injector system 300.
  • Eductor system 440 receives impactors from holding tank 402 and circulates it to hydro-cyclone separator 445 where the impactors are separated from the motive fluid 410 and discharged back into tank 402.
  • the motive fluid 410 is circulated through hydro-cyclone separator 445 and discharged back into tank 408.
  • Fluid holding tank 408 is in flow communication with fluid holding tank 407. Fluid 410 equalizes into holding tank 407 where it is stored as fluid supply fluid 405 for centrifugal charge pump 420.
  • Charge pump 420 pre-charges a high pressure and low volume plunger pump 425.
  • the plunger pump 425 provides motive fluid to operate impactor injector assembly 300.
  • Injector assembly 300 regulates a supply of impactors from impactor storage tank 402 and a high pressure, low volume fluid flow from pump 425 to provide the conditions necessary to generate and discharge a high pressure, low volume highly concentrated impactor slurry into high pressure flow line 455.
  • FIG. 3b illustrates one embodiment of an injector assembly 300 which is comprised of a feed and metering component 345, an impactor accelerator pump component 320, a liquid entrainment venturi component 350 and a fluidic amplifier component 370.
  • the components of injector assembly 300 work together sequentially to pass impactors into the system from an atmospheric condition and to discharge the impactors in the form of a high- pressure slurry.
  • Impactors 335 are gravity fed from tank 402 of FIG. 2 through conduit 332 into conduit 331 which contains a screw type auger (not shown) to be passed through housing 330 into particle impeller pump 320.
  • the screw auger (not shown) is rotated and its speed controlled by the modulated speed of electric motor 333 to meter the flow of impactors 335 into component 320 through housing 330.
  • a hydraulic venturi system may be used to convert pressure into velocity and recover the pressure.
  • a venturi system generates a partial vacuum around a high velocity jet which can be used to entrain solid particles.
  • the hydraulic system has a steady state that will accept solid particles which have to be accelerated into the fluid system. That process absorbs hydraulic energy until a certain threshold is achieved at which point the hydraulic system will collapse.
  • it may be desirable to first accelerate the speed of the solid particles in order to establish an energy neutral or energy positive relationship with the hydraulic eductor.
  • FIG. 3a an impeller wheel 323 is shown retained between housing 322 and cover plate 325 of FIG. 3b which has been removed for clarity purposes. Impeller wheel 323 is rotated in direction 327 by the action of an electric motor 326 of FIG. 3b.
  • the rotating impeller-wheel vanes 324 collect impactors 335 flowing through housing 330 and accelerate the impactors 335 to a high speed and into tangential opening 328 in housing 322 in order to flow through tube 329.
  • Flow tube 329 passes into venturi housing 352 to form a circumferential orifice 353 within the interior of venturi housing 352.
  • Seal and adjustment plate 351 provide a pressure seal to contain internal high pressure and serves as an adjustment mechanism for controlling the circumferential orifice 353 standoff distance.
  • High-pressure fluid is supplied by fluid pump 425 of FIG. 2 through line 426 to the interior cavity 334 of venturi housing 352.
  • the high-pressure fluid is passed though the circumferential orifice 353 to create a venturi jetting effect that serves to generating a low pressure region in front of the distal end of the flow tube 329.
  • the fluid passing through the venturi also serves to entrain the high velocity impactors flowing through flow tube 329 into throat 354, thus forming a slurry of impactors and fluid.
  • the slurry passes through the venturi throat 354 and into the interior chamber of fluidic amplifier component 370.
  • Fluidic amplifier 370 is comprised of a top cap 378 of FIG. 3b, a main body 371, a bottom cap 376 and discharge flow line 455.
  • the slurry from flow line 354 is passed tangentially into interior chamber 372 where it is flowed in a swirling motion and according to the laws of conservation of angular momentum a very high rotational speed is produced at central orifice 373 as the slurry passes through it to chamber 374.
  • the slurry operating according to conservation of angular momentum slows substantially as it passes to the outermost diameter of the chamber 374 where the slurry flows into discharge flow line 455 which is tangentially connected to the outermost diameter of chamber 374.
  • Both end caps of fluidic amplifier 370 have a central vortex stabilizer comprised of stabilizers 377 and 379 to stabilize the vortex flow motion within chambers 372 and 374.
  • the entrainment of impactors in a high-pressure liquid may utilize hydraulic driven eductors that operate on the venturi principle of converting fluid pressure to fluid velocity and subsequently recovering some of the original fluid pressure as the fluid expands in a down stream diffuser section of the eductor at reduced velocity.
  • the eductor system may generate a partial vacuum in close proximity around the periphery of the high-speed axially- flowing motive-fluid jet of the system. This low-pressure region sucks particulate material into the periphery around the jet stream and entrains the material into the motive fluid as it is carried along in the annulus region within the venturi throat and the diffuser wall regions of the eductor as the jet stream expands.
  • the injector may be operated by firstly establishing the venturi flow conditions necessary to operate swirl chamber component system against the pressure of the drilling rig's flow line pressure. Once a steady state flow condition has been established to counterbalance the drilling rig high pressure flow line pressure, the impeller pump is activated and begins to flow impactors into the center of the coaxial jet flow of the venturi section. The velocity imparted by the impeller to the impactors is balanced with the volume of the venturi flow to provide target entrainment ratios. The kinetic energy of the impactors leaving the impeller wheel are designed to allow high impactor ratio entrainment while maintaining the continuous operation of the venturi jet and may equal or exceed the kinetic energy of the venturi jet.
  • the venturi jet will be able to maintain or increase its efficiency of operation while entraining an increasing ratio the impactors.
  • the mass flow of the impactors may account for the greater portion of the mass flow through the venturi throat by supplying the greater amount of kinetic energy necessary to maintain the venturi and swirl chamber sections of the injector providing a mechanism to entraining a very high ratio of impactors to motive liquid, thus achieving the goal of a particle injector that can modulate entraining a broad range of impactor sizes, mixtures, and volumes to generate a highly concentrated, high pressure impactor slurry flow.
  • Impactor entrainment ratios on the order of 60% or greater may be achievable. It can be seen that a very low hydraulic horsepower system can be utilized to entrain a highly concentrated volume of impactors providing the injector system flexibility to optimize the design and operation of the down-hole features of a jet head for boring, conditioning, and directional control of large diameter well bores during their construction.
  • FIG. 4c illustrates an embodiment where a cross-section of a large diameter well bore 700 in which a jet head assembly 800 is situated.
  • Subsurface formations 702 through 708 underlie the earth's surface 701.
  • Formation 702 is illustrated as a siltstone formation
  • formation 703 is illustrated as a water bearing sandstone formation
  • formation 704 is illustrated as a shale formation
  • formation 705 is illustrated as a coal formation
  • formation 706 is illustrated as a second shale formation
  • formation 707 is illustrated as a limestone formation
  • formation 708 is illustrated as a natural gas producing sand stone formation.
  • Pipe string 200 is suspended within the well bore 725 and attached to jet head assembly 800.
  • Surface casing 714 is situated and cemented 715 into formation 702.
  • Casing 716 is situated and cemented 718 in formation 704 as a means isolate water bearing formation 703.
  • Casing 718 is situated and cemented 719 in formation 706 as a means of isolating coal formation 705.
  • Casing 720 is situated and cemented 721 in formation 708 as a means to isolate limestone formation 707.
  • Limestone formation 707 may have natural fractures 709 and 710 as illustrated.
  • Sandstone formation 708 may have natural fractures 711, 712 and 713 as illustrated.
  • FIG. 4 a illustrates an enlarged view of the lower section of the well bore of FIG. 4c.
  • Pipe string 200 is shown attached to jet head assembly 800.
  • the conical shaped end jet 830 and side jets 860 are illustrated issuing from jet head assembly 800.
  • FIG. 4b illustrates an isometric view of the pipe string 200 attached to jet head housing 801 with side jets 860 and conical end jet 830 issuing from the jet head housing 801.
  • Some embodiments of the jet head sub-system of FIGS. 4a-4c utilize a swirling flow fluidic amplifier to generate a conical liquid jet form to maximize the acceleration of the impactors to allow the optimization of impactor particle count, size, and mixture.
  • Some embodiments of the jet head sub-system of the circuit have been designed to simultaneously perform the functions of increasing the velocity of the impactors sufficiently to sustain a high ROP, fo ⁇ n a cutting jet that can be modulated by the slurry properties to change the drilled diameter of the well bore, centralize the jet head through interaction between the jet head and the bottom of the hole, stabilize the jet head through interaction between the jet head and the bottom of the hole, modify the well bore wall through the jetting action of the jet head, and control the direction of the jet head through changing various jetting actions of the jet head.
  • FIG. 5f illustrates an isometric view of one embodiment of a jet head assembly 800.
  • FIG. 5a illustrates an exploded view of the components of the jet head assembly 800.
  • Jet head housing 801 houses stator housing 802 which houses stator 803.
  • Stator 803 is formed with stator channels 820 running axially along the exterior surface of the stator.
  • Swirling flow centralizer and stabilizer 814 extends from the distal end of stator 803. The stem of the stator
  • stator 803 is built with a recessed profile 813 that allows a retrieval tool (not shown) to latch onto the stator assembly for removal.
  • the stator 803 is permanently bonded to stator housing 802.
  • Stator housing 802 is removably latched (latch not shown) to the jet head housing 801. Typical ports
  • stator housing 804 and 805 are providing in stator housing 802 to allow fluid to circulate from the interior of the stator assembly through corresponding typical ports 806 and 807 in jet head housing 801.
  • Nozzles 809 and nozzle retainer 808 are typical of the nozzles and retainers for radially spaced fluid ports typified by fluid ports 806 and 807 and are shown in their seated position in FIG. 5b.
  • FIG. 5b illustrates a cross-sectional view along section lines AA of FIG. 5e.
  • Nozzles typified by nozzle 809 and nozzle retainer 808 are shown in place within jet head housing 801.
  • Stator 803 and stator housing 802 are in place within jet head housing 801.
  • Surfaces 814 and 810 form a first interior cavity for imparting a swirling motion to the fluid passing through this section of the stator assembly.
  • Surfaces 812 and 814 form a second interior cylindrical swirl cavity for the stabilization of the swirling slurry mass.
  • the interior surface of the stator housing 802 forms an exit orifice 811 where the fluid passing through the cylindrical swirl stabilization chamber discharges through the exit orifice 811.
  • FIG. 5c illustrates a side elevation the jet head 801 and pipe string 200.
  • FIG. 5d illustrates the end view of jet head 801.
  • FIG. 5e illustrates end view of jet head 801 with section cutting line AA visible.
  • Some embodiments of the jet head comprise a housing adapted to accept a removable stator assembly and an array of nozzle ports arranged radially around the periphery of the jet head.
  • the stator housing has a first cylindrical shaped internal passageway in which the stator ribs are bonded to its face. This cylindrical section transitions to a converging conically shaped section that in turn transitions to a small diameter cylindrical chamber which both the converging conical section and the small diameter cylindrical section form the swirl chamber of the stator assembly.
  • the swirl chamber section of the stator assembly transitions to an expanding conical shaped exit orifice section.
  • the relative dimensions of the stator assembly flow passages, chambers, and orifices may be optimized to generate a range of operational features that can be modulated by changing the slurry composition and flowing conditions.
  • the slurry is pumped from the pipe string through the passageways created by the stator ribs and the stator housing which imparts an angled swirling motion to the slurry.
  • the angle and initial velocity of the slurry swirling motion is controlled by the exit angle and total flow area of the stator ribs.
  • the slurry flows from the stator channels into the converging conical section of the swirl chamber which serves the functions of imparting an axial flow velocity component into the swirling slurry flow and a chamber to accelerate the swirling slurry flow speed to a substantially higher rotational speed as the slurry flows in ever decreasing diameter circles and finally into the cylindrical flow stabilization section of the swirl chamber.
  • the slurry swirling in the swirl chamber operates according to the law of conversation of angular momentum as the swirling slurry flow progresses from largest swirl chamber diameter to the smaller diameter of the cylindrically shaped swirl chamber section where the slurry rotational flow is stabilized at its maximum speed and allowing the Impactors to maximize their speed prior to passing into the exit orifice region of the stator housing.
  • the drilling fluid component of the slurry during the acceleration of the slurry will be swirling at a greater speed than the impactors.
  • the slurry dwell time in flow stabilization section of the swirl chamber allows the drilling fluid to act on the impactors to maximize the energy transfer to the impactors prior to the swirling flow regime change as the slurry flow transitions into the exit orifice of the stator housing.
  • the high-speed swirling slurry flow transitions from the swirl chamber's flow stabilization section and enters into the exit orifice region of the stator. Due to tangential release fluid dynamics the slurry flow forms a radially flowing cutting jet comprised of relatively high momentum impactors and high velocity drilling fluid flow.
  • the high velocity slurry forms a radially expanding conically shaped cutting jet within the confines of the exit orifice and then extends beyond the exit orifice to form a conically shaped cutting jet which eventually transitions into a reentrant toroidal flowing jet form once the energy of the impinging impactors has been reduced to a level where they cannot further increase the diameter of the well bore under the current operating conditions.
  • the conically shaped cutting jet is forced against the bottom of the well bore by the vertical action jet head as it is allowed to move deeper within the formation being drilled.
  • the exit orifice's concave conical surface comes in close proximity to the matching earthen formation bottom-hole profile being cut by the jetting action of the jet head.
  • the concave conical shape of the exit orifice concurrent with the hydraulic action of the high velocity slurry cutting jet which is further confined between the exit orifice wall and the formation being drilled by the vertical motion of the jet head tends to physically centralize and stabilize the jet head in conjunction to the bottom hole profile generated by the cutting action of the slurry jet.
  • the expanding conical cutting jet formed within the exit orifice region of the stator assembly will eventually form a reentrant toroidal flow regime before the slurry flow is hydraulically released to flow upward within the well bore to carry the entrained impactors and formation cuttings out of the well bore.
  • the slurry cutting jet velocity leveraging feature of the fluidic amplifier of the jet head leverages the slurry flow supply pressure available at the jet head to allow the use of very small impactors while satisfying the CFCS requirement for formation cutting purposes.
  • impactors with a diameter larger than the formation grains will generate fewer impacts per unit of slurry flow and the impinging incidence angle would render a much less impactor impulse energy transfer to the formation.
  • utilizing the smallest practical impactor is desirable from the point of view that they are more easily entrained, circulated throughout high pressure flow line the fluid circuit, circulated out of the well bore, circulated throughout the low pressure flow line circuits, and more easily circulated through existing down hole tools.
  • the jet head can be used to drill and/or under-ream the well bore at high speeds to economically prepare it for the well bore construction savings that may be achieved through the use of monobore well geometry using solid expandable casing methods and/or close tolerance casing nesting practices.
  • FIG. 6d illustrates a cross-section of lower section of a well bore showing one embodiment of well-bore casing 720 cemented into formation 708 by cement sheath 721.
  • Modified well-bore wall surface 871 is shown next to unaffected formation 870 of formation 708.
  • Well bore wall 874 is shown formed by the cutting action of cutting jet 830.
  • Natural fracture 711 is shown adjacent modified well bore 871.
  • a cross-sectional view of a portion of the pipe string 200 and the jet head assembly 800 is shown. Circulation of the pressurized drilling fluid 380 containing impactors 335 is shown flowing through the interior of pipe string 200, through the stator vanes 820 where a swirling motion is imparted to the pressurized drilling fluid 380.
  • the pressurized drilling fluid 380 is shown flowing through lower stator housing 802 and subsequently through exit orifice 811 of FIG. 5b. Within exit orifice 811 of FIG. 5b the pressurized drilling fluid 380 forms an expanding conical shaped cutting jet 830 which cutting action cuts formation 708 forming a bottom hole pattern 732.
  • the cutting action of conical jet 830 cuts the formation face 730 generating formation cuttings 259 that are entrained in the drilling fluid for transportation up the annular space between the jet head body 802, the exterior pipe string 200 and the well bore wall 874 and the interior wall 722 of casing 720 as a returning drilling fluid slurry 255.
  • the return drilling fluid slurry 255 containing impactors and formation cuttings is shown in cross section flowing up only one side of the well bore annulus for clarity purposes.
  • FIG. 6a illustrates the effect of the action of the expanding conical cutting jet 830 flowing into a reentry toroidal shaped flow regime 832.
  • Fluid jet 830 containing impactors 335 cuts the formation face 730 of FIG. 6d and carries the formation cuttings 259 into the reentry toroidal flow 832 where the drilling fluid, impactors 335, and formation cuttings 259 and 733 continue to cut the formation forming face 832.
  • the formation cuttings 259 and impactors 335 circulate in the toroidal flow 832 continuing to cut the formation and are eventually forced out of the toroidal flow 832 to be circulated upwards within the well bore annulus to the drilling rig's surface equipment for processing.
  • FIG. 6b illustrates the circular shaped side jet 861 impacting well bore wall 874 where well bore wall 874 is modified by the jet action of impactors impacting the well bore wall.
  • Modified well bore wall 871 forms a new well bore wall comprised of a thin layer of densified formation material 872.
  • Formation region 870 is the unaffected near well bore region of formation 708.
  • FIG. 6c illustrates natural formation fracture 711 which has been sealed by the action of the side jets 861 and modified formation material 872 to isolate internal pathway of fracture 711 from the well bore and the drilling fluid 255 within well bore 708.
  • FIG. 7d illustrates the front elevation of jet head 801, with horizontal section lines EE, HH and Il shown.
  • FIG. 7a illustrates a cross section about horizontal section line EE that shows four side jet ports within the jet head 801 of which two are blanked off with nozzle port plugs 866 and 867.
  • Two ports contain nozzles with circular shaped orifices that provide the pressurized drilling fluid 380 of FIG. 6d to form horizontal jets 862 and 863 that impinge perpendicularly against the formation 708.
  • FIG. 7b illustrates a cross section about horizontal section line HH that shows four side jet ports within the jet head 801 of which two are blanked off with nozzle port plugs 864 and 865.
  • FIG. 7c illustrates a cross section about horizontal section line II that illustrates an overlay of the 8 jets positioned in the jet head 801.
  • Four of the jets have been selectively blanked 866, 864, 865 and 867 in this case.
  • Four of the jets have been fitted with nozzles with orifice in them 862, 860, 863 and 861. This arrangement of jets produces a net thrust force vectored along thrust vector 820.
PCT/US2008/055895 2007-05-16 2008-03-05 Method and system for particle jet boring WO2008144096A1 (en)

Priority Applications (9)

Application Number Priority Date Filing Date Title
CN200880023970A CN101730783A (zh) 2007-05-16 2008-03-05 用于颗粒喷射钻探的方法和系统
CA002684587A CA2684587A1 (en) 2007-05-16 2008-03-05 Method and system for particle jet boring
US12/599,418 US20100307830A1 (en) 2007-05-16 2008-03-05 Method and system for particle jet boring
JP2010508466A JP2010527418A (ja) 2007-05-16 2008-03-05 粒子ジェットボーリング方法およびシステム
MX2009012259A MX2009012259A (es) 2007-05-16 2008-03-05 Metodo y sistema para perforacion con chorros de particulas.
EP08743686A EP2153011A1 (en) 2007-05-16 2008-03-05 Method and system for particle jet boring
BRPI0811594-0A2A BRPI0811594A2 (pt) 2007-05-16 2008-03-05 Método e sistema para abrir um furo de poço.
AU2008254460A AU2008254460A1 (en) 2007-05-16 2008-03-05 Method and system for particle jet boring
IL202024A IL202024A0 (en) 2007-05-16 2009-11-09 Method and system for particle jet boring

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US93040307P 2007-05-16 2007-05-16
US60/930,403 2007-05-16

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EP (1) EP2153011A1 (pt)
JP (1) JP2010527418A (pt)
CN (1) CN101730783A (pt)
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CA (1) CA2684587A1 (pt)
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US20120217065A1 (en) * 2009-11-19 2012-08-30 Ian Gray System for Analysing Gas From Strata Being Drilled Under High Mud Flows

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US8925653B2 (en) 2011-02-28 2015-01-06 TD Tools, Inc. Apparatus and method for high pressure abrasive fluid injection
CN102251745B (zh) * 2011-06-20 2014-01-08 中国石油集团西部钻探工程有限公司 正压式刚性颗粒高压注入装置
CA2958718C (en) * 2014-06-17 2022-06-14 Daniel Robert MCCORMACK Hydraulic drilling systems and methods
CN104358517A (zh) * 2014-11-20 2015-02-18 陈元 含有固相磨粒的高压射流钻井系统
CN105134080A (zh) * 2015-07-09 2015-12-09 四川川庆石油钻采科技有限公司 一种粒子钻井方法
CN105781420B (zh) * 2016-05-05 2017-12-01 中国石油大学(华东) 粒子冲击钻井检测与控制系统
US11221028B1 (en) 2018-11-29 2022-01-11 Vortex Pipe Systems LLC Cyclonic flow-inducing pump
US10458446B1 (en) 2018-11-29 2019-10-29 Vortex Pipe Systems LLC Material flow amplifier
EP3966416A4 (en) * 2019-05-06 2022-12-14 Services Pétroliers Schlumberger HIGH-PRESSURE DRILLING ASSEMBLY
CN111047961B (zh) * 2020-01-02 2021-11-16 中国石油大学(华东) 水力高压粒子射流钻塞试验装置
US11002301B1 (en) 2020-09-15 2021-05-11 Vortex Pipe Systems LLC Material flow modifier and apparatus comprising same
US11378110B1 (en) 2022-01-05 2022-07-05 Vortex Pipe Systems LLC Flexible fluid flow modifying device
US11739774B1 (en) 2023-01-30 2023-08-29 Vortex Pipe Systems LLC Flow modifying device with performance enhancing vane structure

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CO6251338A2 (es) 2011-02-21
AU2008254460A1 (en) 2008-11-27
CA2684587A1 (en) 2008-11-27
EP2153011A1 (en) 2010-02-17
BRPI0811594A2 (pt) 2014-12-16
JP2010527418A (ja) 2010-08-12
CN101730783A (zh) 2010-06-09
IL202024A0 (en) 2010-06-16
US20100307830A1 (en) 2010-12-09
MX2009012259A (es) 2010-02-17
RU2009146356A (ru) 2011-06-27

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