阅读说明：本技术 一种露天矿用二氧化碳破岩装置及方法 (Carbon dioxide rock breaking device and method for open pit mine ) 是由 李福栋 陈天宇 付彦吉 郑旭 孙子涵 王文芳 宋海国 郝岩屿 于 2021-01-13 设计创作，主要内容包括：一种露天矿用二氧化碳破岩装置及方法,装置包括注气管、增压泵、搅拌式二氧化碳与磨料混合机构、液态二氧化碳储罐、储能室及致裂室,储能室与致裂室之间设有封隔片,注气管上设有压力传感器、流量传感器和若干阀门,储能室与钻孔孔口之间注气管上依次套装有陶瓷电加热套管和保温套管。方法为：布孔；确定破岩参数；钻孔；对钻孔进行热力扩孔；将储能室与致裂室串装体送入钻孔；对钻孔孔口进行封孔；向储能室内腔中通入二氧化碳磨料混合流体,封堵钻孔孔壁裂隙同时加注液态二氧化碳；对液态二氧化碳进行增压和加热,形成超临界二氧化碳并封闭储能室；持续通入超临界二氧化碳使封隔片碎裂,钻孔内液态二氧化碳急速气化膨胀,其能量直接致裂岩层。(A carbon dioxide rock breaking device and method for an open-pit mine comprise a gas injection pipe, a booster pump, a stirring type carbon dioxide and abrasive material mixing mechanism, a liquid carbon dioxide storage tank, an energy storage chamber and a cracking chamber, wherein a sealing spacer is arranged between the energy storage chamber and the cracking chamber, a pressure sensor, a flow sensor and a plurality of valves are arranged on the gas injection pipe, and a ceramic electric heating sleeve and a heat insulation sleeve are sequentially sleeved on the gas injection pipe between the energy storage chamber and a drilling orifice. The method comprises the following steps: arranging holes; determining rock breaking parameters; drilling; carrying out thermal reaming on the drilled hole; feeding the energy storage chamber and the fracturing chamber string assembly into a drill hole; sealing the hole opening of the drill hole; introducing carbon dioxide abrasive mixed fluid into the inner cavity of the energy storage chamber, plugging cracks on the wall of the drilled hole and simultaneously filling liquid carbon dioxide; pressurizing and heating the liquid carbon dioxide to form supercritical carbon dioxide and seal the energy storage chamber; continuously introducing supercritical carbon dioxide to break the packing sheet, rapidly gasifying and expanding the liquid carbon dioxide in the drill hole, and directly cracking the rock stratum by the energy of the liquid carbon dioxide.)

1. The utility model provides a carbon dioxide rock breaking device for open pit mine which characterized in that: comprises a gas injection pipe, a liquid carbon dioxide storage tank, an energy storage chamber and a cracking chamber; the liquid carbon dioxide storage tank is positioned outside the drill hole, and the energy storage chamber and the fracturing chamber are positioned inside the drill hole; one end of the gas injection pipe is communicated with the liquid carbon dioxide storage tank, the other end of the gas injection pipe is communicated with the energy storage chamber, the energy storage chamber and the cracking chamber are connected in series, and the energy storage chamber and the inner cavity of the cracking chamber are separated by a packing piece.

2. The carbon dioxide rock breaking device for the open pit mine according to claim 1, wherein: a first valve, a booster pump, a first pressure sensor, a first flow sensor, a first tee joint, a second valve, a second tee joint, a second pressure sensor, a second flow sensor, a third tee joint and a third valve are sequentially arranged on a gas injection pipe between the liquid carbon dioxide storage tank and a drill hole; a stirring type carbon dioxide and abrasive material mixing mechanism is arranged outside the drill hole, the stirring type carbon dioxide and abrasive material mixing mechanism and a second valve are arranged in parallel, the feeding end of the stirring type carbon dioxide and abrasive material mixing mechanism is communicated with a first tee joint through a fourth valve, and the discharging end of the stirring type carbon dioxide and abrasive material mixing mechanism is communicated with a second tee joint through a fifth valve; and a waste gas storage tank is arranged outside the drill hole and communicated with a third tee joint, and a sixth valve and a third pressure sensor are sequentially arranged on a pipeline between the third tee joint and the waste gas storage tank.

3. The carbon dioxide rock breaking device for the open pit mine according to claim 2, wherein: and the signal output ends of the first pressure sensor, the second pressure sensor, the third pressure sensor, the first flow sensor and the second flow sensor are electrically connected with the information collector, and the signal output end of the information collector is electrically connected with the computer.

4. The carbon dioxide rock breaking device for the open pit mine according to claim 2, wherein: a packer is arranged in a drill hole close to the drill hole opening, and cement mortar is used for plugging a space between the packer and the drill hole opening; and a grouting pump is arranged outside the drilling hole, the grouting pump fills cement mortar into the space between the packer and the drilling hole opening through a grouting pipe, and a seventh valve is arranged on the grouting pipe.

5. The carbon dioxide rock breaking device for the open pit mine according to claim 2, wherein: a ceramic electric heating sleeve and a heat-insulating sleeve are sequentially sleeved on the gas injection pipe between the energy storage chamber and the drill hole from inside to outside; and a temperature controller is arranged outside the drill hole and is electrically connected with the ceramic electric heating sleeve.

6. The carbon dioxide rock breaking device for the open pit mine according to claim 2, wherein: a hole sealing cover plate is arranged above the drilling hole, and a hole sealing gasket and a hole sealing plug are sequentially arranged below the hole sealing cover plate; the hole sealing cover plate is respectively provided with a gas injection pipe penetrating hole and a grouting pipe penetrating hole, and sealants are respectively arranged between the gas injection pipe and the gas injection pipe penetrating hole and between the grouting pipe and the grouting pipe penetrating hole; and the hole sealing cover plate and the drilling surrounding rock are fixed through an anchor rod mechanism.

7. The carbon dioxide rock breaking device for the open pit mine according to claim 1, wherein: the side wall of the energy storage chamber is provided with a plurality of injection nozzles, the outer side of each injection nozzle is provided with a high-pressure closed nozzle, the inner side of a central orifice of the high-pressure closed nozzle is coaxially provided with a thrust spring, one end of the thrust spring is connected with the high-pressure closed nozzle, and the other end of the thrust spring is connected with a nozzle sealing plate; the inner cavity of the energy storage chamber is communicated with the drill hole through an injection nozzle; and the side wall of the fracturing chamber is provided with a plurality of fracturing nozzles, and the inner cavity of the fracturing chamber is communicated with the drill hole through the fracturing nozzles.

8. The carbon dioxide rock breaking method for the open pit mine, which adopts the carbon dioxide rock breaking device for the open pit mine according to claim 1, is characterized by comprising the following steps:

the method comprises the following steps: determining the hole distribution position and the hole distribution quantity of the drill holes according to the mining requirement of the strip mine;

step two: according to the fracturing range and the lumpiness requirement required by strip mine exploitation, determining the pressure and the flow of the fracturing rock mass and the plugging cracks formed by injecting the carbon dioxide and the grinding material in a mixing manner;

step three: drilling holes at the determined hole distribution positions by using drilling equipment, and performing thermal reaming on the drilled holes after the drilled holes reach a preset depth to enable the drilled holes to form a shape of thin top and thick bottom;

step four: the method comprises the following steps of (1) sending a string assembly of an energy storage chamber and a fracturing chamber into a drill hole, then sending a packer to a specified position in the drill hole, and then starting the packer;

step five: sequentially completing installation of a hole sealing plug, a hole sealing gasket and a hole sealing cover plate at a drill hole opening, then opening a seventh valve, then starting a grouting pump, filling cement mortar into a space between the packer and the drill hole opening through a grouting pipe until the space is filled with the cement mortar, then sequentially closing the grouting pump and the seventh valve, and finally waiting for the cement mortar to reach consolidation strength, and completing hole sealing;

step six: the first valve, the third valve, the fourth valve and the fifth valve are adjusted to be in an opening state, the other valves are maintained in a closing state, the booster pump and the stirring type carbon dioxide and abrasive material mixing mechanism are started simultaneously, the pressure of the booster pump is set, liquid carbon dioxide output from the liquid carbon dioxide storage tank is firstly boosted by the booster pump and then enters the stirring type carbon dioxide and abrasive material mixing mechanism to be mixed with abrasive materials, the formed carbon dioxide and abrasive material mixed fluid directly enters an inner cavity of the energy storage chamber through the gas injection pipe, the nozzle sealing plate is in an opening state at the moment, the carbon dioxide and abrasive material mixed fluid can smoothly shoot to the hole wall of the drill hole through the injection nozzle and the high-pressure closed nozzle to plug cracks in the hole wall of the drill hole, so that a relatively closed space is formed in the drill hole, and then the stirring type carbon, after the crack is plugged, continuously introducing carbon dioxide fluid into the drill hole 5 until the liquid carbon dioxide amount in the drill hole meets the requirement, then closing all valves in the opening state, and simultaneously closing the booster pump;

step seven: adjusting the first valve, the second valve and the third valve to be in an opening state, maintaining the rest valves in a closing state, starting the booster pump and the ceramic electric heating sleeve, continuously boosting carbon dioxide output from the liquid carbon dioxide storage tank by the booster pump to be more than 7.4MPa, heating the boosted carbon dioxide to be more than 31.1 ℃ after passing through the ceramic electric heating sleeve until supercritical carbon dioxide is formed and enters the inner cavity of the energy storage chamber, so that the pressure in the inner cavity of the energy storage chamber is rapidly increased and exceeds the spring force of the thrust spring, closing the nozzle sealing plate under the pressure, further closing the high-pressure closing nozzle, and finally forming a closed space in the inner cavity of the energy storage chamber;

step eight: continuously introducing supercritical carbon dioxide into the inner cavity of the energy storage chamber to continuously increase the pressure in the inner cavity of the energy storage chamber until the pressure exceeds the limit which can be borne by the sealing and separating piece, so that the sealing and separating piece is cracked, at the moment, the high-pressure supercritical carbon dioxide in the inner cavity of the energy storage chamber instantly enters the inner cavity of the cracking chamber and is ejected out through the cracking nozzle, the liquid carbon dioxide in the drill hole is subjected to phase change and rapid gasification and expansion under the impact action, and the energy generated in the process is directly subjected to rock stratum cracking;

step nine: and closing the booster pump and the ceramic electric heating sleeve, adjusting the first valve and the second valve to be in a closed state, maintaining the opening state of the third valve, simultaneously opening the sixth valve, continuously maintaining the closed state of the other valves, and recovering the waste gas through the waste gas storage tank and realizing pressure relief.

Technical Field

The invention belongs to the technical field of surface mine mining, and particularly relates to a carbon dioxide rock breaking device and method for surface mines.

Background

Strip mining is a process of removing a covering on an ore body to obtain required minerals, generally comprising the operation processes of stripping, blasting, mining, loading and the like, wherein the blasting process is a key link influencing the mining quality, safety and economic benefit of the ore body. The traditional blasting mode utilizes the explosive gas that explodes produced of explosive in drilling to reach the purpose that sends and splits the rock, but traditional blasting mode exists a great deal of potential safety hazard, and the explosive easily causes the incident in storage, transportation, and the explosive can arouse great air shock wave when using, not only can bring noise, environmental pollution, and great seismic wave still can influence the slope stability moreover, and then has brought serious secondary disaster. In addition, high-temperature explosive gas is easy to lose coal bodies in the drill holes in the blasting process of open-pit coal mining, and a large amount of resources are wasted.

Therefore, a carbon dioxide blasting technology is developed, the carbon dioxide blasting is performed by using the phase change conversion characteristic of carbon dioxide, but the carbon dioxide needs to be compressed into a blasting barrel in advance, and the carbon dioxide needs to be subjected to phase change by using a detonation mode such as electric percussion or explosive percussion during use, so that the volume of the carbon dioxide is expanded instantly to achieve the blasting effect. The electric firing detonation mode or the explosive firing detonation mode has certain danger in the explosive gas environment, and meanwhile, higher potential safety hazards exist in the process of compressing carbon dioxide into the blasting cartridge.

For coal mines, the generation of excessive foam coal in the traditional blasting process causes a great deal of resource waste and reduced benefit, so that the coal body after rock breaking is required to have certain lumpiness. For metal ores, the large block rate is required to be reduced as much as possible after rock breaking so as to meet the requirements of lifting and mineral separation. The traditional carbon dioxide blasting adopts the blasting cartridge to store energy, can not adjust and control the energy, and is difficult to satisfy the lumpiness demand of different ore rock masses. In addition, because the pore wall of opencast rock drilling has natural crack, can increase the gaseous phase transition and produce the dissipation passageway of energy, do not adopt the hole sealing to handle in the traditional carbon dioxide blasting process simultaneously, aggravated energy dissipation and produced dust pollution, lead to that current carbon dioxide blasting mode exists that the broken rock scope is little, broken rock effect is unsatisfactory etc. weak point.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a carbon dioxide rock breaking device and method for an open-pit mine, which have the characteristics of high rock breaking safety, large rock breaking range, good rock breaking effect and controllable pressure and lumpiness.

In order to achieve the purpose, the invention adopts the following technical scheme: a carbon dioxide rock breaking device for open mines comprises a gas injection pipe, a liquid carbon dioxide storage tank, an energy storage chamber and a cracking chamber; the liquid carbon dioxide storage tank is positioned outside the drill hole, and the energy storage chamber and the fracturing chamber are positioned inside the drill hole; one end of the gas injection pipe is communicated with the liquid carbon dioxide storage tank, the other end of the gas injection pipe is communicated with the energy storage chamber, the energy storage chamber and the cracking chamber are connected in series, and the energy storage chamber and the inner cavity of the cracking chamber are separated by a packing piece.

A first valve, a booster pump, a first pressure sensor, a first flow sensor, a first tee joint, a second valve, a second tee joint, a second pressure sensor, a second flow sensor, a third tee joint and a third valve are sequentially arranged on a gas injection pipe between the liquid carbon dioxide storage tank and a drill hole; a stirring type carbon dioxide and abrasive material mixing mechanism is arranged outside the drill hole, the stirring type carbon dioxide and abrasive material mixing mechanism and a second valve are arranged in parallel, the feeding end of the stirring type carbon dioxide and abrasive material mixing mechanism is communicated with a first tee joint through a fourth valve, and the discharging end of the stirring type carbon dioxide and abrasive material mixing mechanism is communicated with a second tee joint through a fifth valve; and a waste gas storage tank is arranged outside the drill hole and communicated with a third tee joint, and a sixth valve and a third pressure sensor are sequentially arranged on a pipeline between the third tee joint and the waste gas storage tank.

And the signal output ends of the first pressure sensor, the second pressure sensor, the third pressure sensor, the first flow sensor and the second flow sensor are electrically connected with the information collector, and the signal output end of the information collector is electrically connected with the computer.

A packer is arranged in a drill hole close to the drill hole opening, and cement mortar is used for plugging a space between the packer and the drill hole opening; and a grouting pump is arranged outside the drilling hole, the grouting pump fills cement mortar into the space between the packer and the drilling hole opening through a grouting pipe, and a seventh valve is arranged on the grouting pipe.

A ceramic electric heating sleeve and a heat-insulating sleeve are sequentially sleeved on the gas injection pipe between the energy storage chamber and the drill hole from inside to outside; and a temperature controller is arranged outside the drill hole and is electrically connected with the ceramic electric heating sleeve.

A hole sealing cover plate is arranged above the drilling hole, and a hole sealing gasket and a hole sealing plug are sequentially arranged below the hole sealing cover plate; the hole sealing cover plate is respectively provided with a gas injection pipe penetrating hole and a grouting pipe penetrating hole, and sealants are respectively arranged between the gas injection pipe and the gas injection pipe penetrating hole and between the grouting pipe and the grouting pipe penetrating hole; and the hole sealing cover plate and the drilling surrounding rock are fixed through an anchor rod mechanism.

The side wall of the energy storage chamber is provided with a plurality of injection nozzles, the outer side of each injection nozzle is provided with a high-pressure closed nozzle, the inner side of a central orifice of the high-pressure closed nozzle is coaxially provided with a thrust spring, one end of the thrust spring is connected with the high-pressure closed nozzle, and the other end of the thrust spring is connected with a nozzle sealing plate; the inner cavity of the energy storage chamber is communicated with the drill hole through an injection nozzle; and the side wall of the fracturing chamber is provided with a plurality of fracturing nozzles, and the inner cavity of the fracturing chamber is communicated with the drill hole through the fracturing nozzles.

The carbon dioxide rock breaking method for the open pit mine adopts the carbon dioxide rock breaking device for the open pit mine and comprises the following steps:

the method comprises the following steps: determining the hole distribution position and the hole distribution quantity of the drill holes according to the mining requirement of the strip mine;

step two: according to the fracturing range and the lumpiness requirement required by strip mine exploitation, determining the pressure and the flow of the fracturing rock mass and the plugging cracks formed by injecting the carbon dioxide and the grinding material in a mixing manner;

step three: drilling holes at the determined hole distribution positions by using drilling equipment, and performing thermal reaming on the drilled holes after the drilled holes reach a preset depth to enable the drilled holes to form a shape of thin top and thick bottom;

step four: the method comprises the following steps of (1) sending a string assembly of an energy storage chamber and a fracturing chamber into a drill hole, then sending a packer to a specified position in the drill hole, and then starting the packer;

step five: sequentially completing installation of a hole sealing plug, a hole sealing gasket and a hole sealing cover plate at a drill hole opening, then opening a seventh valve, then starting a grouting pump, filling cement mortar into a space between the packer and the drill hole opening through a grouting pipe until the space is filled with the cement mortar, then sequentially closing the grouting pump and the seventh valve, and finally waiting for the cement mortar to reach consolidation strength, and completing hole sealing;

step six: the first valve, the third valve, the fourth valve and the fifth valve are adjusted to be in an opening state, the other valves are maintained in a closing state, the booster pump and the stirring type carbon dioxide and abrasive material mixing mechanism are started simultaneously, the pressure of the booster pump is set, liquid carbon dioxide output from the liquid carbon dioxide storage tank is firstly boosted by the booster pump and then enters the stirring type carbon dioxide and abrasive material mixing mechanism to be mixed with abrasive materials, the formed carbon dioxide and abrasive material mixed fluid directly enters an inner cavity of the energy storage chamber through the gas injection pipe, the nozzle sealing plate is in an opening state at the moment, the carbon dioxide and abrasive material mixed fluid can smoothly shoot to the hole wall of the drill hole through the injection nozzle and the high-pressure closed nozzle to plug cracks in the hole wall of the drill hole, so that a relatively closed space is formed in the drill hole, and then the stirring type carbon, after the crack is plugged, continuously introducing carbon dioxide fluid into the drill hole 5 until the liquid carbon dioxide amount in the drill hole meets the requirement, then closing all valves in the opening state, and simultaneously closing the booster pump;

step seven: adjusting the first valve, the second valve and the third valve to be in an opening state, maintaining the rest valves in a closing state, starting the booster pump and the ceramic electric heating sleeve, continuously boosting carbon dioxide output from the liquid carbon dioxide storage tank by the booster pump to be more than 7.4MPa, heating the boosted carbon dioxide to be more than 31.1 ℃ after passing through the ceramic electric heating sleeve until supercritical carbon dioxide is formed and enters the inner cavity of the energy storage chamber, so that the pressure in the inner cavity of the energy storage chamber is rapidly increased and exceeds the spring force of the thrust spring, closing the nozzle sealing plate under the pressure, further closing the high-pressure closing nozzle, and finally forming a closed space in the inner cavity of the energy storage chamber;

step eight: continuously introducing supercritical carbon dioxide into the inner cavity of the energy storage chamber to continuously increase the pressure in the inner cavity of the energy storage chamber until the pressure exceeds the limit which can be borne by the sealing and separating piece, so that the sealing and separating piece is cracked, at the moment, the high-pressure supercritical carbon dioxide in the inner cavity of the energy storage chamber instantly enters the inner cavity of the cracking chamber and is ejected out through the cracking nozzle, the liquid carbon dioxide in the drill hole is subjected to phase change and rapid gasification and expansion under the impact action, and the energy generated in the process is directly subjected to rock stratum cracking;

step nine: and closing the booster pump and the ceramic electric heating sleeve, adjusting the first valve and the second valve to be in a closed state, maintaining the opening state of the third valve, simultaneously opening the sixth valve, continuously maintaining the closed state of the other valves, and recovering the waste gas through the waste gas storage tank and realizing pressure relief.

The invention has the beneficial effects that:

1. the safety is improved. According to the invention, carbon dioxide is injected outside the drill hole of the original carbon dioxide blasting cartridge, and is converted into injection in the drill hole, and a phase change expansion process is generated in the drill hole, so that unsafe factors brought by the carbon dioxide blasting cartridge are avoided, and simultaneously, sparks and explosives are not generated in the whole blasting process, so that the safety is improved.

2. The rock breaking range is increased. The traditional carbon dioxide blasting cartridge is limited in carbon dioxide carrying amount, and the rock breaking range and energy are improved by increasing the carbon dioxide amount and expanding holes.

3. The rock breaking effect is enhanced. Because the carbon dioxide abrasive mixed fluid is used for plugging the cracks of the drill hole and the hole sealing treatment mode is adopted for the drill hole, the dissipation channel of the fracturing energy is reduced, the rock breaking effect is enhanced, and the consumption of the carbon dioxide is reduced.

4. The pressure is controllable. The effective control of the fracturing energy is realized by controlling the pressure and the flow, the requirement of the rock breaking degree of different ore rock bodies is met, and the grade of ore resource is improved.

In conclusion, the carbon dioxide rock breaking device and method for the strip mine have the characteristics of high rock breaking safety, large rock breaking range, good rock breaking effect and controllable pressure and block size.

Drawings

FIG. 1 is a schematic structural diagram of a carbon dioxide rock breaking device for an open pit mine, which is disclosed by the invention;

FIG. 2 is a schematic view of the accumulator chamber of the present invention in operation within a borehole;

FIG. 3 is a schematic view of the fracturing chamber of the present invention as it functions within a borehole;

FIG. 4 is a schematic structural view of a high pressure closed sprinkler head (not blocked by a spout sealing plate) of the present invention;

FIG. 5 is a schematic view of the high pressure closed nozzle of the present invention (blocked by the spout closure plate);

FIG. 6 is a schematic view of the sealing cover plate of the present invention assembled with some components;

in the figure, 1-an air injection pipe, 2-a liquid carbon dioxide storage tank, 3-an energy storage chamber, 4-a cracking chamber, 5-a drilling hole, 6-a sealing spacer, 7-a booster pump, 8-a first pressure sensor, 9-a first flow sensor, 10-a second pressure sensor, 11-a second flow sensor, 12-a stirring type carbon dioxide and abrasive mixing mechanism, 13-a waste gas storage tank, 14-a third pressure sensor, 15-a packer, 16-cement mortar, 17-a grouting pump, 18-a grouting pipe, 19-a ceramic electric heating sleeve, 20-a heat insulation sleeve, 21-a temperature controller, 22-a sealing cover plate, 23-a sealing gasket, 24-a sealing plug, 25-an air injection pipe penetrating hole, 26-a grouting pipe penetrating hole, 27-a sealant, 28-an anchor rod mechanism, 29-an injection nozzle, 30-a high-pressure closed nozzle, 31-a thrust spring, 32-a nozzle sealing plate, 33-a cracking nozzle, v1-first valve, V2-second valve, V3-third valve, V4-fourth valve, V5-fifth valve, V6-sixth valve, V7-seventh valve, T1-first tee, T2-second tee, T3-third tee.

Detailed Description

The invention is described in further detail below with reference to the figures and the specific embodiments.

As shown in fig. 1 to 6, the carbon dioxide rock breaking device for the open pit mine comprises a gas injection pipe 1, a liquid carbon dioxide storage tank 2, an energy storage chamber 3 and a cracking chamber 4; the liquid carbon dioxide storage tank 2 is positioned outside the drill hole 5, and the energy storage chamber 3 and the fracturing chamber 4 are positioned inside the drill hole 5; one end of the gas injection pipe 1 is communicated with the liquid carbon dioxide storage tank 2, the other end of the gas injection pipe 1 is communicated with the energy storage chamber 3, the energy storage chamber 3 and the cracking chamber 4 are connected in series, and the energy storage chamber 3 and the inner cavity of the cracking chamber 4 are separated by a packing sheet 6.

A first valve V1, a booster pump 7, a first pressure sensor 8, a first flow sensor 9, a first tee T1, a second valve V2, a second tee T2, a second pressure sensor 10, a second flow sensor 11, a third tee T3 and a third valve V3 are sequentially arranged on the gas injection pipe 1 between the liquid carbon dioxide storage tank 2 and the orifice of the drill 5; a stirring type carbon dioxide and abrasive mixing mechanism 12 is arranged outside the drill hole 5, the stirring type carbon dioxide and abrasive mixing mechanism 12 and a second valve V2 are arranged in parallel, the feeding end of the stirring type carbon dioxide and abrasive mixing mechanism 12 is communicated with a first tee T1 through a fourth valve V4, and the discharging end of the stirring type carbon dioxide and abrasive mixing mechanism 12 is communicated with a second tee T2 through a fifth valve V5; an exhaust gas storage tank 13 is arranged outside the drill hole 5, the exhaust gas storage tank 13 is communicated with a third tee joint T3, and a sixth valve V6 and a third pressure sensor 14 are sequentially arranged on a pipeline between the third tee joint T3 and the exhaust gas storage tank 13.

An information collector and a computer are arranged outside the drill hole 5, the signal output ends of the first pressure sensor 8, the second pressure sensor 10, the third pressure sensor 14, the first flow sensor 9 and the second flow sensor 11 are electrically connected with the information collector, and the signal output end of the information collector is electrically connected with the computer.

A packer 15 is arranged in the drill hole 5 close to the hole opening of the drill hole 5, and the space between the packer 15 and the hole opening of the drill hole 5 is blocked by cement mortar 16; an injection pump 17 is arranged outside the borehole 5, the injection pump 17 fills cement mortar 16 into a space between the packer 15 and the orifice of the borehole 5 through an injection pipe 18, and the injection pipe 18 is provided with a seventh valve V7.

A ceramic electric heating sleeve 19 and a heat insulation sleeve 20 are sequentially sleeved on the gas injection pipe 1 between the energy storage chamber 3 and the orifice of the drill hole 5 from inside to outside; a temperature controller 21 is arranged outside the borehole 5, and the temperature controller 21 is electrically connected with the ceramic electric heating sleeve 19.

A hole sealing cover plate 22 is arranged above the hole opening of the drill hole 5, and a hole sealing gasket 23 and a hole sealing plug 24 are sequentially arranged below the hole sealing cover plate 22; a gas injection pipe penetrating hole 25 and a grouting pipe penetrating hole 26 are respectively formed in the hole sealing cover plate 22, and sealant 27 is respectively arranged between the gas injection pipe 1 and the gas injection pipe penetrating hole 25 and between the grouting pipe 18 and the grouting pipe penetrating hole 26; the hole sealing cover plate 22 and the surrounding rock of the drill hole 5 are fixed through an anchor rod mechanism 28.

A plurality of injection nozzles 29 are formed in the side wall of the energy storage chamber 3, a high-pressure closed nozzle 30 is arranged on the outer side of each injection nozzle 29, a thrust spring 31 is coaxially arranged on the inner side of a central orifice of the high-pressure closed nozzle 30, one end of the thrust spring 31 is connected with the high-pressure closed nozzle 30, and the other end of the thrust spring 31 is connected with a nozzle sealing plate 32; the inner cavity of the energy storage chamber 3 is communicated with the drill hole 5 through an injection nozzle 29; the side wall of the cracking chamber 4 is provided with a plurality of cracking nozzles 33, and the inner cavity of the cracking chamber 4 is communicated with the drill hole 5 through the cracking nozzles 33.

In the embodiment, the gas injection pipe 1, the grouting pipe 18 and other pipelines are all made of high-strength, high-pressure-resistant, wear-resistant and antistatic pipes; the grinding material in the stirring type carbon dioxide and grinding material mixing mechanism 12 is powder sand with the grain diameter smaller than 1 mm; the anchor rod body and the anchoring hole in the anchor rod mechanism 28 are fixed through an expansive type resin anchoring agent, and extrusion force is generated on surrounding rock of the anchoring hole through the self-expansion characteristic of the anchoring agent so as to improve the anchoring force; and the sealant 27 arranged between the grouting pipe 18 and the grouting pipe penetrating hole 26 adopts AB glue.

The carbon dioxide rock breaking method for the open pit mine adopts the carbon dioxide rock breaking device for the open pit mine and comprises the following steps:

the method comprises the following steps: determining the hole distribution position and the hole distribution quantity of the drill holes 5 according to the mining requirement of the strip mine;

step two: according to the fracturing range and the lumpiness requirement required by strip mine exploitation, determining the pressure and the flow of the fracturing rock mass and the plugging cracks formed by injecting the carbon dioxide and the grinding material in a mixing manner;

step three: at the determined hole distribution position, machining a drill hole 5 by using drilling equipment, and performing thermal reaming on the drill hole 5 after the drill hole 5 reaches a preset depth to enable the drill hole 5 to form a shape of being thin at the top and thick at the bottom; the drilling holes 5 in the shapes of thin upper parts and thick lower parts can increase the filling quality of carbon dioxide and are also beneficial to improving the rock breaking range and energy;

step four: sending the string assembly of the energy storage chamber 3 and the fracturing chamber 4 into a borehole 5, then sending a packer 15 into a specified position in the borehole 5, and then starting the packer 15;

step five: the installation of a hole sealing plug 24, a hole sealing gasket 23 and a hole sealing cover plate 22 is sequentially completed at the hole opening of the drill hole 5, then a seventh valve V7 is opened, then an grouting pump 17 is started, cement mortar 16 is filled into the space between the packer 15 and the hole opening of the drill hole 5 through a grouting pipe 18 until the space is filled with the cement mortar 16, then the grouting pump 17 and the seventh valve V7 are sequentially closed, and finally the completion of hole sealing is waited for the cement mortar 16 to reach the consolidation strength;

step six: the first valve V1, the third valve V3, the fourth valve V4 and the fifth valve V5 are adjusted to be in an open state, the other valves are maintained in a closed state, the booster pump 7 and the stirring type carbon dioxide and abrasive mixing mechanism 12 are started at the same time, the pressure of the booster pump 7 is set, liquid carbon dioxide output from the liquid carbon dioxide storage tank 2 is firstly pressurized by the booster pump 7 and then enters the stirring type carbon dioxide and abrasive mixing mechanism 12 to be mixed with abrasive, the formed carbon dioxide and abrasive mixed fluid directly enters an inner cavity of the energy storage chamber 3 through the gas injection pipe 1, the nozzle sealing plate 32 is in an open state at the moment, the carbon dioxide and abrasive mixed fluid can smoothly shoot to the hole wall of the drill hole 5 through the injection nozzle 29 and the high-pressure closed nozzle 30 to plug cracks in the drill hole 5, so that a relatively closed space is formed in the drill hole 5, then, the stirring type carbon dioxide and abrasive material mixing mechanism 12 is closed, after fracture plugging is completed, carbon dioxide fluid is continuously introduced into the drill hole 5 until the amount of liquid carbon dioxide in the drill hole 5 meets the requirement, then all valves in an opening state are closed, and the booster pump 7 is closed;

step seven: adjusting a first valve V1, a second valve V2 and a third valve V3 to be in an opening state, maintaining the rest valves in a closing state, simultaneously starting a booster pump 7 and a ceramic electric heating sleeve 19, continuously boosting carbon dioxide output from a liquid carbon dioxide storage tank 2 by the booster pump 7 to be more than 7.4MPa, heating the boosted carbon dioxide to be more than 31.1 ℃ after passing through the ceramic electric heating sleeve 19 until supercritical carbon dioxide is formed and enters an inner cavity of an energy storage chamber 3, further rapidly increasing the pressure in the inner cavity of the energy storage chamber 3, and exceeding the spring force of a thrust spring 31, at the moment, closing a nozzle sealing plate 32 under the pressure, further closing a high-pressure closing nozzle 30, and finally forming a closed space in the inner cavity of the energy storage chamber 3;

step eight: continuously introducing supercritical carbon dioxide into the inner cavity of the energy storage chamber 3 to continuously increase the pressure in the inner cavity of the energy storage chamber 3 until the pressure exceeds the limit which can be borne by the isolating piece 6, so that the isolating piece 6 is cracked, at the moment, the high-pressure supercritical carbon dioxide in the inner cavity of the energy storage chamber 3 instantly enters the inner cavity of the cracking chamber 4 and is ejected out through the cracking nozzle 33, the liquid carbon dioxide in the drill hole 5 is subjected to phase change and rapid gasification expansion under the impact action, and the energy generated in the process directly cracks a rock stratum;

step nine: the booster pump 7 and the ceramic electric heating sleeve 19 are closed, the first valve V1 and the second valve V2 are adjusted to be in a closed state, the open state of the third valve V3 is maintained, meanwhile, the sixth valve V6 is opened, and the rest of the valves continue to be in a closed state, at the moment, the waste gas is recovered through the waste gas storage tank 13, and pressure relief is realized. In the process of injecting liquid carbon dioxide into the borehole 5, pressure data and flow data can be acquired in real time through the first pressure sensor 8, the second pressure sensor 10, the first flow sensor 9 and the second flow sensor 11, the purpose of controlling the pressure can be achieved by controlling the opening and closing of the booster pump 7 and the third valve V3, the opening state of the third valve V3 is maintained, the pressure of the booster pump is set, the pressure can be continuously increased, and the booster pump 7 and the third valve V3 are closed, so that the pressurization is stopped. By taking open pit coal mining as an example, the loss of the fracturing fluid is controlled through drilling hole sealing and fracture plugging, so that the dissipation of the fracturing energy is avoided. By controlling the pressure and the injection amount, the total energy of coal body cracking is further controlled, the coal body lumpiness is finally controlled, the amount of the coal foam is effectively reduced, and the resource utilization and the economic benefit are improved.

The embodiments are not intended to limit the scope of the present invention, and all equivalent implementations or modifications without departing from the scope of the present invention are intended to be included in the scope of the present invention.