EP4278066A1 - Borehole sealing and improved foam properties for controlled foam injection (cfi) fragmentation of rock and concrete - Google Patents
Borehole sealing and improved foam properties for controlled foam injection (cfi) fragmentation of rock and concreteInfo
- Publication number
- EP4278066A1 EP4278066A1 EP21704148.2A EP21704148A EP4278066A1 EP 4278066 A1 EP4278066 A1 EP 4278066A1 EP 21704148 A EP21704148 A EP 21704148A EP 4278066 A1 EP4278066 A1 EP 4278066A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- foam
- barrel
- poppet
- piston
- sand
- Prior art date
- Legal status (The legal status 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 status listed.)
- Pending
Links
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- 238000002347 injection Methods 0.000 title claims abstract description 52
- 239000007924 injection Substances 0.000 title claims abstract description 52
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- 238000013467 fragmentation Methods 0.000 title description 4
- 238000006062 fragmentation reaction Methods 0.000 title description 4
- 238000007789 sealing Methods 0.000 title description 4
- 239000000126 substance Substances 0.000 claims abstract description 36
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 24
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- 239000004576 sand Substances 0.000 claims description 92
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- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 77
- 239000007789 gas Substances 0.000 description 12
- 239000003380 propellant Substances 0.000 description 9
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- GUJOJGAPFQRJSV-UHFFFAOYSA-N dialuminum;dioxosilane;oxygen(2-);hydrate Chemical compound O.[O-2].[O-2].[O-2].[Al+3].[Al+3].O=[Si]=O.O=[Si]=O.O=[Si]=O.O=[Si]=O GUJOJGAPFQRJSV-UHFFFAOYSA-N 0.000 description 1
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Classifications
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21C—MINING OR QUARRYING
- E21C37/00—Other methods or devices for dislodging with or without loading
- E21C37/06—Other methods or devices for dislodging with or without loading by making use of hydraulic or pneumatic pressure in a borehole
- E21C37/12—Other methods or devices for dislodging with or without loading by making use of hydraulic or pneumatic pressure in a borehole by injecting into the borehole a liquid, either initially at high pressure or subsequently subjected to high pressure, e.g. by pulses, by explosive cartridges acting on the liquid
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21C—MINING OR QUARRYING
- E21C37/00—Other methods or devices for dislodging with or without loading
- E21C37/06—Other methods or devices for dislodging with or without loading by making use of hydraulic or pneumatic pressure in a borehole
Definitions
- the invention provides improvements to the method and apparatus for breaking rock and concrete, based upon a Controlled-Foam Injection or PCF (Penetrating Cone Fracture) process wherein a high-pressure fluid is used to pressurize a pre-drilled hole of appropriate geometry.
- PCF Packetrating Cone Fracture
- the invention provides automated methods, apparatus and techniques for forming a high pressure seal between the injection barrel and the walls of the prerequisite pre-drilled hole in the material to be broken and removal and wash-out of said seal to free the injection barrel from its location.
- Improved leak free poppet valves hold a fluid in a pressure vessel and rapidly discharge it.
- Generating and delivering variable charges of foam and water to the breaker includes prefilling the injection barrel with a low viscosity fluid.
- An annular reverse acting poppet valve allows concurrent injection of chemical additives and/or micro particles to modify foam viscosity during its high pressure release into the material to be broken.
- An improved high pressure foam generator construction is compact and reliable, and allows
- the current invention provides improvements to continuous excavation/demolition systems based upon the controlled fracturing of hard competent rock and concrete by Controlled Foam Injection (CFI) and Penetrating Cone Fracture (PCF) processes.
- CFI Controlled Foam Injection
- PCF Penetrating Cone Fracture
- Both CFI and PCF methods as outlined in commonly owned Patents U.S. 6,375,271 and U.S. 5,098,163 deliver a pressurized fluid to the bottom of a hole previously drilled into the material to be broken.
- Patents U.S. 6,375,271 and U.S. 5,098,163 are hereby incorporated by reference in their entirety as if fully set forth herein.
- This new PLC (Programmable Logic Controller) based pneumatic system automatically delivers a sufficient volume of sand directly to the seal cavity. Furthermore, it engages the hydraulic system to effectively crush the sand in the sand filled cavity to form a very effective high pressure seal.
- an improved poppet is described with a novel self-aligning conical valve seat that reduces leakage and enhances operational durability and resilience against surface defects.
- the host material to be broken varies physically in terms of porosity, parting plane geometry, discontinuities and composition. These variations may adversely affect the fracture size, sometimes developing large enough gaps that result in incomplete breakage of the host rock. To avoid this result it is desirable to dramatically increase the viscosity of the foam as it is travels through the fractures so that high foam injection pressures are maintained.
- This invention describes a unique annular poppet apparatus capable of injecting a pressurized stream of reactive liquid simultaneously into the main flow release of foam that will subsequently increase the foam viscosity.
- the present invention provides both method and apparatus for automating the formation and optional removal of a high-pressure sand seal without the adverse penalties of manual operations and consequent delays.
- the invention includes a Programmable Logic Controlled (PLC) pneumatic sand delivery system capable of metering, transporting and placing a sufficient quantity of the preferred sand from a pressurized sand hopper to the seal annular compartment or cavity. Both the seal cavity and the sand are dimensioned such that the cavity captures the sand and holds it firmly in place. Following the sand placement, the PLC or operator can engage hydraulic valving that actuates the crushing and packing of the captured sand and forms it into a fine granular and compact annular layer seal. This crushed sand layer creates a high-pressure seal that tightly locks the injection barrel into the borehole and prevents leakage between the hole bottom and the exterior. By locking the barrel in position against the material to be broken, recoil forces are minimized or eliminated thus reducing the cyclic stresses on the carrier and equipment.
- PLC Programmable Logic Controlled
- the seal is effective even when the drilled borehole is not circular or uniform and is of varying diameter. These are all realities in rotary percussive drilling and the new seal is effective in all these application.
- the sand is kept dry in a mine environment of 100% humidity and dry sand is kept in the hopper.
- the injection barrel position lock provided by the sand seal proves sufficiently effective to occasionally necessitate a technique of freeing the injection barrel from the material to be broken.
- the preferred embodiment of the invention provides the method and means of liberating the injection barrel by washing out the crushed sand seal.
- the present invention incorporates porting and valving within the apparatus to enable the selective delivery of a comingled flow of compressed air and pressurized water down along the injection barrel directed at the crushed sand seal annulus. The turbulence and agitation of the comingled stream combined with the oscillatory movement of the crush tube erodes and washes out the exposed finely crushed sand, thus effecting the removal of the seal and the release of the barrel.
- the present invention incorporates an improved poppet valve with a hard-conical cross-sectional piston that self-aligns against a softer mating conical seat.
- the harder poppet piston can mechanically deform any seat surface imperfections and conform hermetically to its mating surface, thus eliminating subsequent leakage.
- the large surface area afforded by the conical seat forces the poppet piston to conform to any axial misalignment between them and be held in a stable position by the fluid back pressure.
- the footprint of the high pressure foam generator has been minimized by housing the viscosity enhancing chemical injection apparatus internally.
- this apparatus was housed externally as an additional narrow piston/cylinder extension to the main body. This shorter internal construction eliminates this failure possibility and additionally limits concentric misalignments between cylinder walls and pistons.
- Figure 1 is a foreshortened detailed cutaway side view of the injection barrel and crush tube subassembly in a retracted position for the automated delivery of sand to the sand seal cavity.
- Figure 2 is a foreshortened detailed cutaway side view of the injection barrel and crush tube subassembly in an extended position, showing the device inserted in a predrilled hole after sand seal emplacement locking the barrel in the host rock.
- Figure 3 shows side cross-sectional, perspective cross-sectional and perspective views and cross-sections of the present PLC controlled pneumatic sand delivery apparatus.
- Figure 4 is a detailed cross-sectional view of the barrel and the annular poppet valve for injecting modifying agents into the main foam release flow.
- Figures 5a and 5b are a close-up view of the annular poppet valve depicted in Figure 4 with the piston seal closed and open, respectively.
- Figures 6a, 6b and 6c show three detailed cross-sectional views of a simplified poppet valve with a conical seat.
- Figure 7 is a foreshortened perspective cross-sectional view of the same poppet valve depicted in Figure 6 with a reduced part count.
- Figure 8 shows a double acting foam generating system with a pressure regulator capable of supplying foam with variable gas quality and viscosity enhancing chemicals to the breaker.
- Figure 9 is a cross sectional view of the compact foam generator apparatus with the piston core assembly centered.
- Figure 10 is a schematic representation of the control.
- the automated seal placement system includes the following elements: a PLC (Programmable Logic Controller) controlled air pressurized sand hopper and metering apparatus, pressure resistant hoses and conduits linking the sand hopper to the breaker barrel shown in Figure 1, and the seal cavity within the host rock formed in the void between the barrel, barrel bulb tip, borehole and crush tube end.
- a PLC Programmable Logic Controller
- Appropriate sand and a low-pressure compressor capable of delivering a steady and sufficient flow of compressed air to the system are also needed.
- the automated seal emplacement is accomplished by first pre-drilling the host rock and inserting the retracted breaker barrel 2 assembly of Figure 1 into the borehole 19 as shown in Figure 2.
- the crush tube 3 and crush piston assembly 13 is initially in its retracted position, thus connecting the sand groove 4 to the nose cone 5 sand port 9 through crush tube opening 6.
- the seal emplacement operation is initiated at will by the operator of the continuous mining machine, by simply pressing a button on a suitable control panel that transmits the command to the PLC.
- the PLC is appropriately programed to open a pneumatic electro valve that opens compressed air flow to the sand hopper 22 that has a lid 21 in Figure 3.
- the PLC then activates a relay that turns on roller motor 27 on the sand hopper 22 while still maintaining it pressurized and with a continuous flow of air.
- the rollers 24 are geared together 29 and begin counter rotating against each other, thus metering vertically, a steady stream of sand in through funnel 23 and out through funnel 25.
- the gaps between the rollers are calibrated to meter an optimal flow of sand into the air flow stream and to avoid stoppage or plugging of the lines by excessive sand volume.
- the sand thus fed enters the stream flow of compressed air 26 and travels with it all the way to the seal cavity 18.
- the grains of sand are of such a diameter that the majority of them are trapped in the seal cavity 18 as they are too large to escape to the exterior through the gaps between the borehole wall 19 and the crush tube 3 or to the hole bottom through the gap between the borehole 19 and the conical bulb tip 1 that forces the sand outward.
- the PLC maintains the steady flow of air down the sand lines and to the sand seal cavity 18. This ensures that the lines and conduits are cleared of any remaining sand and prevents settling of the sand into accumulations that could cause stoppages or plugging.
- the PLC then closes the pneumatic electro valve that stops compressed air flow to the sand hopper 22. All air pressure in the hopper 22 is vented through the sand line 26 to the exterior.
- the PLC or operator now sequences the crushing of the sand accumulated in the sand seal cavity 18 by actuating the electrohydraulic valve that ports hydraulic fluid pressure into the crush tube cylinder 14.
- the PLC monitors two suitable sensors, one measures the distance traveled by the crush tube and the other measures the hydraulic pressure acting on the crush tube piston 13.
- the PLC software can numerically calculate an estimate of the crush tube travel with just one pressure sensor.
- the PLC software first measures the time interval taken between the activation of the crush tube and the resulting pressure peak at end of travel and then multiplies that time by the pre-established constant extension velocity of the crush tube. Once at end of travel, the PLC compares the distance traveled by the crush tube 3 to a predetermined maximum. If the traveled distance by the crush tube is below this threshold, the PLC determines a successful seal emplacement and crush operation. The operator is notified appropriately by a suitable pilot light on the control console. If, however the distance exceeds the threshold, the PLC sets an error pilot light to alert the operator of the failure of the seal emplacement operation. In this way, the operator is notified of the success or failure of the automated seal placement and can proceed appropriately with either subsequent breakage operations or further seal emplacement efforts.
- the crush tube 3 remains under significant force, pressed against the annular sand seal 18 by action of the hydraulic pressure acting on piston 13 that remains trapped in the cylinder 14.
- the bulb tip 1 is in contact with the sand seal through its unique conical outer surface.
- the trapped sand is thus crushed into a fine siliceous powder that forms a remarkably impervious seal.
- the seal firmly binds the barrel 2 to the host rock 17 through the resulting seal’s outstanding coefficient of friction.
- the conicity of the bulb tip 1 is defined by the angle between the barrel axis and its surface.
- a nominal angle of 20 degrees is used and is shown in the preferred embodiment. However, that angle can be varied and optimized for specific rock types, fracture patterns and ease of barrel extraction.
- the crush tube 3 is extended such that the sand groove 4 is isolated from the seal cavity 18, thus preventing stoppage of the sand barrel groove 4 by accumulation of crushed sand at its end.
- the crush access tube hole 6 is aligned with the wash out port 7 in nose cone 5, thus enabling the barrel groove 4 to act as a conduit for seal wash out fluids.
- the barrel assembly can be extracted from the borehole 19 most easily by the effective removal of the crushed sand seal. This operation is initiated when the operator activates a set of electro valves that directs a stream of comingled water and pressurized air into the nose cone wash out port 7 through an appropriate hose.
- This jet is directed through crush tube access hole 6 into barrel groove 4 which leads directly to the annular seal cavity 19.
- the agitation provided by the turbulent flow of the comingled stream will erode the crushed sand material and cause the fine particles to be transported to the exterior of the borehole.
- the operator hydraulically oscillates the crush tube, further agitating and dislodging the crushed sand seal particles and suspending them within the surrounding stream of bubbling water.
- Repeated crushing of the sand by the crush tube 3 reduces the particles to a fine dust that once suspended in the wash out fluid easily escapes through the surrounding borehole 19 gaps to the exterior.
- the comingled stream of water and air is prevented from back flowing into the nose cone sand conduit hole 8 by the portion of the crush tube that now covers the opening
- the sand grain size, mineral composition and geometry aid emplacement and effectiveness of the seal.
- Sand that includes a majority of grains that are not sufficiently rounded or too moist and or contain oversized particles is prone to create stoppages and plugs within the conduits during seal emplacement.
- Sand that is of insufficient diameter will not be trapped in the seal cavity 18 and thus escape to either the exterior or the hole bottom.
- Sand whose mineral composition does not include sufficient quartz may not offer a sufficient coefficient of friction to prevent the barrel from escaping when the bottom of the hole is fully pressurized.
- Field tests show that the ideal sand grain is 8-12 sieve size is well rounded and crushes to a fine powder.
- “Frac Sand”, which is sand mostly used as proppant in the oil industry has been successfully tested in this method and provides ideal specifications. Synthetic proppants, such as sintered bauxite, although not yet tested, might satisfy the preferred specifications.
- the quartz sand placement and sealing system can also be used in conjunction with a conventional propellant based rock breaking method (PCF) which would reduce the energy, and thus the charge size required for adequate breakage of the rock or concrete. Consequently, the reduced charge size would minimize the adverse effects of high air blast, fly rock, toxic fumes and noise associated with standard PCF breaks.
- PCF propellant based rock breaking method
- FIG. 4 A cross-sectional view of an improved CFI breaker is shown in Figure 4.
- a specialized annular poppet valve allows for the simultaneous injection of a liquid chemical into the flow of foam during its release. The addition of the chemical serves to increase the foam viscosity or alter its composition so as to improve its rock breaking characteristics.
- a cross linker or other liquid foam modifying chemical
- the injection of a cross linker, or other liquid foam modifying chemical is effected by the differential motion of the smaller injection tube 81, acting as a piston, inside the injection cavity 82 in the injection cylinder 83.
- the injection cylinder 83 is threaded into the foam piston 84 and is displaced along with the foam piston as foam is released down the barrel.
- Appropriate high-pressure seals 86 isolate the injection chamber from the high-pressure foam 39 and the high-pressure air pad 78 compartments.
- the rapid change in volume of the chemical chamber 82 occurs simultaneously with and proportional to the release of foam down the barrel 2, thus forcing the modifying chemical out of tube 81 and into the throat 92 of the poppet core shown in Figures 5a and 5b.
- the foam thus is comingled with the injected chemical on its travel through the barrel, and the desired change in viscosity or breaking characteristics is achieved during the breakage process.
- the chemical liquid is replenished in the injection cavity 82 through the fixed tube 87 from the foam generator 55 shown in Figure 8 and occurs simultaneously with the delivery of the foam load to the breaker 59 in Figure 8.
- the tube 87 also provides a sliding seal between the motion of the injection cylinder 83, and the Breaker air pad compartment 78. It is threaded directly into the rear breaker plug 88.
- FIGs 5a and 5b A close-up view of the annular type poppet is shown in Figures 5a and 5b within the main foam cylinder 40 and is composed of an internal poppet cylinder 75, annular poppet piston 76 and the poppet core 77.
- the through hole poppet valve allows for access to the inside of the barrel 4 for injecting selected additives to the flow of high-pressure foam as it is being released through the barrel to the borehole bottom.
- the poppet piston 76 is held firmly closed by using the high-pressure air from the air pad section 78 shown in Figure 4 that has been ported to air cavity 80 through access port 89 shown in Figure 5b.
- the high-pressure air in the cavity 80 is vented to the exterior via port 89 and by appropriate external valving. This allows the stored foam in the breaker to push open the annular poppet piston 76 to the left, thus uncovering the four slanted access ports 90 in the poppet core 77.
- the poppet core includes four access ports 90 equally spaced radially which allows the foam to escape through its throat 92 and into the barrel 4.
- the unique annular poppet allows access to the borehole bottom for performing specific operations at the borehole bottom independently of the injection of high-pressure foam for breakage.
- a small-charge propellant system could be used to provide a high-pressure pulse of short duration that initiates bottom hole fractures conducive to complete fragmentation of the material.
- Such propellant charge add-on system would incorporate a rotating ball check valve within the throat 92 of the poppet core that can be used to feed a small propellant charge down the barrel preceding the injection of low-pressure foam or gel.
- the propellant charge could contain a pressure sensitive switch to ignite the propellant. Most, if not all, of the energy for breakage would come from the propellant.
- the propellant system can be deployed rapidly to fracture and break a uniquely hard compact material, whenever such might be encountered in normal CFI operations.
- Foam modifying substance may be fed directly into the bore of the barrel 4 through the poppet valve throat from opening 91.
- the foam modifying substances are chemicals such as cross-linking chemicals and small particles such as proppants used in oil and gas wells. Small particles include micro and nano-sized particles.
- the unique poppet valve shown in Figures 6a, 6b, 6c and 7 mitigates potential leaks of the pressurized fluid 39 held in the breaker 40 from escaping down the barrel through the poppet outlet 36.
- This compact construction is backwards compatible with the main structural features of the breaker assembly depicted in Figure 4 and Figure 5.
- the breaker centerplate 16 and main cylinder 40 are identical in both figures.
- the poppet valve itself consists of three main components: The annular stationary core 32; the free piston 33; and the adapter cylinder 34.
- the core 32 provides both the valve seat 41 and the guide cylinder for the piston 33.
- the piston 33 is made out of a hard maraging steel alloy, and the core 32 is made out of softer stainless steel.
- valve seat 41 This provides a valve seat 41 whose surface imperfections may be deformable by the closing action of the piston 33.
- a solid plug 35 screws in to the back of the core 30 that allows for manual piston 33 insertion and removal. It also forms the backstop for the cylindrical chamber 43 that houses the piston 33.
- the geometry of the core 32 contains four large slanted holes 31 arranged perpendicular to each other that terminate at the junction of the valve seat 41. To close the poppet, pressurized air that matches that of the fluid in the breaker 39, is ported into the cylindrical poppet core chamber 43 via the four mutually perpendicular access ports 37 and 38.
- FIG. 6a, 6b and 6c An alternate embodiment of this poppet configuration with a reduced part count is shown in Figure?.
- the annular adapter flange 34 has been combined with the core 32 as shown in Figures 6a, 6b and 6c has been made into one piece 45, thereby simplifying the overall construction and eliminating the need for the intermediary O-ring seals.
- the floating piston 44 During sudden discharge of the pressurized fluid 39, the floating piston 44 achieves substantial momentum that unless checked can result in damage to itself and or the poppet assembly.
- the annular adapter flange 34 serves as a forward stop to the floating piston assembly 44 and provides sufficient area to dissipate the impact without damage.
- Shown in Figure 8 is a plumbing diagram of the PLC controlled automated foam generating and delivery system.
- a foam generator 55 is attached to the breaker 59, via high pressure gas lines and associated valving 51-58.
- the foam generator mixes two primary components, namely the liquid phase that is over 95 percent water and the gas phase that is normal atmospheric air compressed to the desired foam pressure.
- the liquid phase may contain gels and thickeners to increase viscosity as well as surfactants comprising less than 2 percent of the liquid phase.
- Standard check valves 56 control the direction of flow.
- the high-pressure gas entering ports 46 and 49 may be provided by any conventional compressor or intensifier system.
- Gel liquid through port 48 is supplied by a conventional high-pressure liquid pump through valve 52.
- the system is capable of automatically sequencing the delivery three different types of loads to the breaker 59: foam; high viscosity foam; and or water.
- the PLC controls the state of the feed valves 51-54 and 58 as well as the internal hydraulic piston displacement of the foam generator 55.
- the system is also created to allow the operator to selectively pre-load the breaker barrel with water. Low viscosity water can be fed via port 50 through valves 54 and 58 to the breaker barrel, with the intention of initiating fractures at the bottom of the hole at lower relative foam pressures.
- the PLC allows the operator to tailor the desired foam viscosity, injection pressure as well as the quantity and type of foam loads depending on the fragmentation characteristics of the material to be broken. For example, the operator can deliver additional foam loads to the breaker with the effect of increasing the injection pressure at the bottom of the hole. The operator could choose to only load low viscosity water charges into the breaker which is helpful in fracturing competent homogenous fine grained and low porosity rocks.
- the PLC is programmed to automatically open the foam release valve 62 if overpressure or other failure conditions are detected by the PLC and/or operator.
- One embodiment of the delivery system also includes a high-pressure regulator 60 in between the high-pressure gas line 49 and the input to the air cylinder 48 of the foam generator.
- the quality of the foam in the CFI breaker can be controlled between 50 % to 0 % quality (per cent of gas) by varying the pressure in the gas cylinder 48 through the pressure regulator 60.
- This regulator can lower the effective pressure in the gas cylinder as compared to the pressure of the air pad section 78 of the breaker 59, thus resulting in lower pressure foam being delivered to the water/foam cylinder of the foam generator 55.
- this foam is delivered to the breaker it is compressed up to the air pad pressure in chamber 78. Consequently, this compression will reduce the gas quality of the foam being delivered to the breaker.
- the automated foam generation and delivery system of Figure 8 can be mounted directly on the rock or concrete breaking machine utilizing the built-in diesel/hydraulic or electric/hydraulic power sources.
- the automated foam generation and delivery system can be mounted on a separate “power pack” machine that incorporates the necessary power sources and is attached or towed behind the rock or concrete breaking unit and is connected by means of high-pressure flexible tubing and hoses.
- Figure 9 shows a detailed cross-sectional side view of a compact high-pressure foam generator.
- the foam generator is composed of a concentric outer cylinder assembly that houses an internal piston core.
- the cross link piston 63 and cylinder assembly 67 are housed internally, thus shrinking the foam generator’s footprint and providing additional safety margin in case of mechanical failure.
- embedded electronic position sensors 74 at either end of the foam generator provide the PLC with piston core position feedback information. The PLC controls both the direction of movement and start and stop timing of the piston core.
- the small stationary diameter tubular rod 63 acts as a piston within the cylindrical cavity 67 and is used to inject cross-linking liquid 47.
- the micro-metering cylinder 67 is incorporated within the Gel piston 64 and functions like a syringe, thus delivering the chemical solution on a proportional basis to the piston core leftward displacement.
- Figure 10 is a schematic representation of the control system that shows the PLC 100 and its main sensors, the foam pad pressure sensor 110, the air pad pressure sensor 112 and the hydraulic sensor 114, foam generator left position sensor 116 and right position sensor 118.
- the operator control panel 120 has button switches for sand seal 122, stop 124, seal crush 126, pressure adjustment 128, water load 132, cross link load 134 and foam load 136.
- Seal button 122 starts a sand seal delivery and emplacement cycle.
- Fire switch 140 sequences the sudden discharge of the breaker to release the foam load into the material to be broken.
- Breaker flush switch 142 starts water and pressurized air to remove the crushed sand seal.
- Two important electro hydraulic valves are the crush tube extend and retract valves 150 for crushing and packing the sand seal and the foam generator gel/water stroke valves 152 for displacing the foam generator piston core to either end.
- PLC output 161 turns the sand metering rollers motor 162 on and switch 164 operates air valve 166 that pressurizes the sand delivery system as set by regulator 168.
- Water to barrel valve 170 controls pre-loading the barrel with low viscosity fluid.
- Valve 172 opens and closes the supply of foam modifying substance to the foam generator.
- the foam modifying substance may be a chemical or chemicals, for example cross-linking chemicals or small particles which are supplies or small-charge propellants.
- Gel close valve 174 controls the flow of gel to the foam generator.
- Air and water open valves 176, 178 control high pressure air and water to the foam generator.
- Fire valve 180 allows the sudden discharge of the poppet back pressure in order to release the foam load in the breaker. While the invention has been described with reference to specific embodiments, modifications and variations of the invention may be constructed without departing from the scope of the invention, which is defined in the following claims.
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- Engineering & Computer Science (AREA)
- Mining & Mineral Resources (AREA)
- Life Sciences & Earth Sciences (AREA)
- General Life Sciences & Earth Sciences (AREA)
- Geochemistry & Mineralogy (AREA)
- Geology (AREA)
- Consolidation Of Soil By Introduction Of Solidifying Substances Into Soil (AREA)
- Drilling And Exploitation, And Mining Machines And Methods (AREA)
- Disintegrating Or Milling (AREA)
Abstract
Description
Claims
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/US2021/013561 WO2022154797A1 (en) | 2021-01-15 | 2021-01-15 | Borehole sealing and improved foam properties for controlled foam injection (cfi) fragmentation of rock and concrete |
Publications (1)
Publication Number | Publication Date |
---|---|
EP4278066A1 true EP4278066A1 (en) | 2023-11-22 |
Family
ID=74562089
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP21704148.2A Pending EP4278066A1 (en) | 2021-01-15 | 2021-01-15 | Borehole sealing and improved foam properties for controlled foam injection (cfi) fragmentation of rock and concrete |
Country Status (9)
Country | Link |
---|---|
EP (1) | EP4278066A1 (en) |
JP (1) | JP2024505823A (en) |
KR (1) | KR20230145573A (en) |
AU (1) | AU2021418701B2 (en) |
CA (1) | CA3204933A1 (en) |
MX (1) | MX2023008415A (en) |
PE (1) | PE20240494A1 (en) |
WO (1) | WO2022154797A1 (en) |
ZA (1) | ZA202108841B (en) |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
SE7607337L (en) * | 1976-06-28 | 1977-12-29 | Atlas Copco Ab | KIT AND DEVICE FOR BREAKING A SOLID MATERIAL |
AU534676B2 (en) * | 1978-10-16 | 1984-02-09 | Alwyn Halley Cheney | Rock breaker |
US5098163A (en) | 1990-08-09 | 1992-03-24 | Sunburst Recovery, Inc. | Controlled fracture method and apparatus for breaking hard compact rock and concrete materials |
US6102484A (en) * | 1996-07-30 | 2000-08-15 | Applied Geodynamics, Inc. | Controlled foam injection method and means for fragmentation of hard compact rock and concrete |
US6375271B1 (en) | 1999-04-30 | 2002-04-23 | Young, Iii Chapman | Controlled foam injection method and means for fragmentation of hard compact rock and concrete |
-
2021
- 2021-01-15 EP EP21704148.2A patent/EP4278066A1/en active Pending
- 2021-01-15 PE PE2023002090A patent/PE20240494A1/en unknown
- 2021-01-15 CA CA3204933A patent/CA3204933A1/en active Pending
- 2021-01-15 KR KR1020237027577A patent/KR20230145573A/en unknown
- 2021-01-15 WO PCT/US2021/013561 patent/WO2022154797A1/en active Application Filing
- 2021-01-15 MX MX2023008415A patent/MX2023008415A/en unknown
- 2021-01-15 AU AU2021418701A patent/AU2021418701B2/en active Active
- 2021-01-15 JP JP2023543081A patent/JP2024505823A/en active Pending
- 2021-11-09 ZA ZA2021/08841A patent/ZA202108841B/en unknown
Also Published As
Publication number | Publication date |
---|---|
WO2022154797A1 (en) | 2022-07-21 |
KR20230145573A (en) | 2023-10-17 |
CA3204933A1 (en) | 2022-07-21 |
AU2021418701B2 (en) | 2024-09-12 |
PE20240494A1 (en) | 2024-03-15 |
MX2023008415A (en) | 2023-10-19 |
AU2021418701A1 (en) | 2023-08-24 |
ZA202108841B (en) | 2022-11-30 |
JP2024505823A (en) | 2024-02-08 |
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