REAR-MOUNTED DOUBLE-CHANNEL ABRASIVE JET CUTTING DEVICE

Abstract

The present invention relates to a rear-mounted double-channel abrasive jet cutting device, and belongs to the field of coal seam pressure relief and permeability improvement, which mainly comprises an ultra-high pressure clean water pump, an ultra-high pressure hose, an ultra-high pressure rotary water swivel, an abrasive pumping device, an abrasive rotary sealing water swivel, a double-channel sealing drill pipe and a double-channel cutter. A jet power source is provided by the ultra-high pressure clean water pump, and safe transfer of high pressure water is ensured by the ultra-high pressure hose, the ultra-high pressure rotary water swivel and the double-channel sealing drill pipe; an abrasive sand adding channel is formed by the abrasive pumping device, the abrasive rotary sealing water swivel, the double-channel sealing drill pipe and the double-channel cutter to achieve separate double-channel supply of high pressure water transfer and abrasive transfer. By innovatively inventing the double-channel abrasive jet cutting device, wear of a high pressure hose and a drilling tool caused by abrasive and high pressure water during mixed transfer is avoided. At the same time, the linear pressure loss of the high pressure water is avoided, which greatly improves the coal breaking capacity of high pressure water jet cutting and prolongs the service life of the device.

Claims

1. A preparation method for a nanoparticle copper-iron composite alloy, characterized by comprising the following steps: under a high-temperature protective atmosphere, adding nanoparticles to the molten Cu/Fe alloy by physical and/or chemical means, mixing and dispersing them evenly, then casting the uniformly mixed Cu/Fe melt containing nanoparticles into a billet, followed by post-processing of the billet; wherein (a) The nanoparticles must possess thermal and chemical stability, without decomposition or reaction with the matrix elements (Fe, Cu) during the preparation process; (b) The nanoparticles (NP) must have thermodynamic stability at the interface between the growing phase (Fe) and the matrix phase (Cu); the NP/Fe and NP/Cu interface free energies should be close to each other, leading to a significant reduction in total system interface energy; (c) the nanoparticles should quickly migrate to the growth interface (Fe/Cu interface); wherein the size of the nanoparticles is 50-100 nm.

2. The preparation method according to claim 1, characterized in that the physical addition method involves wrapping the nanoparticles in metal foil; and/or the chemical addition method involves a molten salt-assisted process, wherein the molten salt-assisted process includes mixing nanoparticles with molten salt before adding them to the Cu/Fe alloy solution; and/or, after adding the nanoparticles to the molten Cu/Fe alloy, the mixing and dispersing method is mechanical stirring or high-energy ultrasonic stirring.

3. The preparation method according to claim 2, characterized in that the metal foil is iron foil or copper foil.

4. The preparation method according to claim 1, characterized in that the post-processing method involves one or more deformation-aging treatments.

5. The preparation method according to claim 1, characterized in that the mass fraction of Fe in the molten Cu/Fe alloy is 5-50 wt. %.

6. The preparation method according to claim 1, characterized in that the nanoparticles occupy 1-20% of the volume of the alloy solution.

7. The preparation method according to claim 1, characterized in that the nanoparticles are selected from at least one of ceramic carbide nanoparticles, ceramic nitride nanoparticles, ceramic oxide nanoparticles, and ceramic boride nanoparticles.

8. The preparation method according to claim 7, characterized in that the nanoparticles are selected from at least one of SiC, MoC, WC, Al.sub.2O.sub.3, BN, and TiB.sub.2.

9. A nanoparticle copper-iron composite alloy prepared by the method according to any one of claims 1-8.

10. The application of the method according to any one of claims 1-8 in the preparation of copper-iron alloys.

Description

DESCRIPTION OF THE DRAWINGS

[0019] To enable the purpose, the technical solution and the advantages of the present invention to be more clear, the present invention will be preferably described in detail below in combination with the drawings, wherein:

[0020] FIG. 1 is a structural schematic diagram of a device of the present invention;

[0021] FIG. 2 is a structural schematic diagram of an abrasive rotary sealing water swivel;

[0022] FIG. 3 is a structural schematic diagram of a double-channel sealing drill pipe; and

[0023] FIG. 4 is a structural schematic diagram of a double-channel cutter in a jet condition;

[0024] Reference signs: ultra-high pressure clean water pump 1-1; ultra-high pressure hose 1-2; ultra-high pressure rotary water swivel 1-3; abrasive tank 2-1; feeding pump 2-2; pressure cap 2-3; abrasive transfer hose 2-4; abrasive rotary sealing water swivel 2-5; double-channel sealing drill pipe 2-6; double-channel cutter 2-7; drill bit 2-8; water swivel outer wall 2-5a; water swivel inner wall 2-5b; sealing rotary body 2-5c; sealing rotary body outer bayonet 2-5d; sealing bearing 2-5e; abrasive feeding hole 2-5f; water swivel abrasive transfer hole 2-5g; water swivel abrasive channel 2-5h; water swivel high pressure water channel 2-5i; drill pipe outer wall 2-6a; drill pipe inner wall 2-6b; drill pipe abrasive channel 2-6c; drill pipe abrasive transfer hole 2-6d; drill pipe high pressure water channel 2-6e; cutter outer wall 2-7a; cutter inner wall 2-7b; cutter abrasive channel 2-7c; cutter abrasive transfer hole 2-7d; nozzle 2-7e; nozzle hole 2-7f; nozzle abrasive transfer hole 2-7g; cutter high pressure water channel 2-7h; spring 2-7i; pressure relief baffle 2-7j.

DETAILED DESCRIPTION OF THE INVENTION

[0025] Embodiments of the present invention are described below through specific embodiments. Those skilled in the art can understand other advantages and effects of the present invention easily through the disclosure of the description. The present invention can also be implemented or applied through additional different specific embodiments. All details in the description can be modified or changed based on different perspectives and applications without departing from the spirit of the present invention. It should be noted that the figures provided in the following embodiments only exemplarily explain the basic conception of the present invention, and if there is no conflict, the following embodiments and the features in the embodiments can be mutually combined.

[0026] Wherein the drawings are only used for exemplary description, are only schematic diagrams rather than physical diagrams, and shall not be understood as a limitation to the present invention. In order to better illustrate the embodiments of the present invention, some components in the drawings may be omitted, scaled up or scaled down, and do not reflect actual product sizes. It should be understandable for those skilled in the art that some well-known structures and description thereof in the drawings may be omitted.

[0027] Same or similar reference signs in the drawings of the embodiments of the present invention refer to same or similar components. It should be understood in the description of the present invention that terms such as upper, lower, left, right, front and back indicate direction or position relationships shown based on the drawings, and are only intended to facilitate the description of the present invention and the simplification of the description rather than to indicate or imply that the indicated device or element must have a specific direction or constructed and operated in a specific direction, and therefore, the terms describing position relationships in the drawings are only used for exemplary description and shall not be understood as a limitation to the present invention; for those ordinary skilled in the art, the meanings of the above terms may be understood according to specific conditions.

[0028] As shown in FIG. 1 to FIG. 4, a rear-mounted double-channel abrasive jet cutting device is disclosed, which can realize double-channel separate transfer of high pressure water and abrasive, and can avoid problems such as heavy wear of a high pressure transfer pipeline caused by a mixed transfer process. The present invention mainly comprises an ultra-high pressure water jet supply system I and an abrasive supply system II. A continuous water jet power source is provided by the ultra-high pressure water jet supply system I, abrasive transfer is provided by the abrasive supply system II, and a high pressure abrasive jet is formed by mixing at the front end of a cutter, thus to enhance a hitting force of a water jet. The ultra-high pressure water jet supply system I comprises an ultra-high pressure clean water pump 1-1, an ultra-high pressure hose 1-2 and an ultra-high pressure rotary water swivel 1-3, wherein the ultra-high pressure clean water pump 1-1 is matched and in communication with the ultra-high pressure rotary water swivel 1-3 by the ultra-high pressure hose 1-2; The abrasive supply system II comprises an abrasive tank 2-1, a feeding pump 2-2, a pressure cap 2-3, an abrasive transfer hose 2-4 and an abrasive rotary sealing water swivel 2-5, wherein the abrasive tank 2-1 is matched and in communication with the abrasive rotary sealing water swivel 2-5 by the abrasive transfer hose 2-4; the ultra-high pressure rotary water swivel 1-3 is matched and in communication with the abrasive rotary sealing water swivel 2-5; a double-channel sealing drill pipe 2-6, a double-channel cutter 2-7 and a drill bit 2-8 are matched and connected in sequence on one side away from the ultra-high pressure clean water pump and installed on a drilling rig.

[0029] High pressure water of 100 MPa can be provided by the ultra-high pressure clean water pump 1-1, bearing pressure of the ultra-high pressure hose 1-2 is 160 MPa, and bearing pressure of the ultra-high pressure rotary water swivel 1-3 is 160 Mpa; the abrasive tank 2-1 has a volume of 100 L, a ratio of height to diameter of 6:1 and a bearing pressure of 30 MPa. The feeding pump 2-2 has a power of 5 KW and a pumping pressure of 15 MPa. The abrasive transfer hose 2-4 is a steel wire spiraled rubber hose with a pipe diameter of 32 mm and a bearing pressure of 30 MPa; particle size of the abrasive sand is 80 meshes, and sand-to-water ratio of the mixture in the abrasive tank is 2:1; the abrasive rotary sealing water swivel can realize rotary dynamic sealing of the abrasive sand, and has a bearing pressure of 160 MPa.

[0030] The structure of the abrasive rotary sealing water swivel comprises a water swivel outer wall 2-5a, a water swivel inner wall 2-5b, a sealing rotary body 2-5c, a sealing rotary body outer bayonet 2-5d, sealing bearings 2-5e, an abrasive feeding hole 2-5f, a water swivel abrasive transfer hole 2-5g and a water swivel abrasive channel 2-5h. Sealing bearings 2-5e are installed on both ends of the sealing rotary body 2-5c which is embedded between the water swivel outer wall 2-5a and the sealing rotary body outer bayonet 2-5d. Six abrasive feeding holes 2-5f are symmetrically distributed in both sides of the water swivel inner wall 2-5b, the diameter of each hole is 10 mm, and the distance between holes is 100 mm. Four water swivel abrasive transfer holes 2-5g are annularly and symmetrically distributed at a junction between the water swivel outer wall 2-5a and the water swivel inner wall 2-5b, and the diameter of each hole is 5 mm.

[0031] The structure of the double-channel sealing drill pipe comprises a pipe outer wall 2-6a, a drill pipe inner wall 2-6b, a drill pipe abrasive channel 2-6c, drill pipe abrasive transfer holes 2-6d and a drill pipe high pressure water channel 2-6e. Four drill pipe abrasive transfer holes 2-6d are annularly and symmetrically distributed at a junction between the drill pipe outer wall 2-6a and the drill pipe inner wall 2-6b, and the diameter of each hole is 5 mm. The double-channel sealing drill pipe can realize double-channel sealing transfer of the abrasive and the high pressure water, and has a bearing pressure of 120 MPa.

[0032] The double-channel cutter is provided with an abrasive transfer channel and a high pressure water transfer channel, and the high pressure water transfer channel has a function of water jet high and low pressure conversion. In a high pressure jet condition, and under an abrasive pumping action and a siphon action of the high pressure water, the abrasive is ejected together with a high pressure water jet to form the abrasive jet;

[0033] The structure of the double-channel cutter comprises a cutter outer wall 2-7a, a cutter inner wall 2-7b, a cutter abrasive channel 2-7c, a cutter abrasive transfer hole 2-7d, a nozzle 2-7e, a nozzle hole 2-7f, nozzle abrasive transfer holes 2-7g, a cutter high pressure water channel 2-7h, a spring 2-7i and a pressure relief baffle 2-7j. Four cutter abrasive transfer holes 2-7d are annularly and symmetrically distributed at a junction between the cutter outer wall 2-7a and the cutter inner wall 2-7b, and the diameter of each hole is 5 mm. A high and low pressure conversion control valve is formed by the spring 2-7i and the pressure relief baffle 2-7j, and the conversion value is 15 MPa. The nozzle 2-7e has the nozzle hole 2-7f and the nozzle abrasive transfer holes 2-7g, and the diameter of the nozzle hole 2-7f can be 2.5 mm; two nozzle abrasive transfer holes 2-7g are symmetrically distributed in a column of the nozzle 2-7e, and the diameter of each hole is 5 mm.

[0034] The high and low pressure conversion control valve is formed by the spring 2-7i and the pressure relief baffle 2-7j, a high and low pressure conversion threshold can be set by selecting springs of different specifications, and the conversion threshold can be 10 MPa, 15 MPa or 20 Mpa. When supplied water pressure is lower than the high and low pressure conversion threshold, the pressure relief baffle 2-7j is located at the rear end of the cutter, and water flows out from the front end. When the water pressure is higher than the threshold, the pressure relief baffle 2-7j is pushed to the front end, the water flowing out from the front end is cut off, and all the water are ejected from the nozzle 2-7e to form a high pressure jet. The nozzle 2-7e has the nozzle hole 2-7f and the nozzle abrasive transfer holes 2-7g, and the diameter of the nozzle hole 2-7f can be 2.5 mm, 3.0 mm or 3.5 mm. Two nozzle abrasive transfer holes 2-7g are symmetrically distributed in a column of the nozzle 2-7e, and the diameter of each hole is 5 mm.

[0035] A use method of the present invention comprises the following steps: [0036] a. Hole drilling construction. Connecting the double-channel sealing drill pipe 2-6, the double-channel cutter 2-7 and the drill bit 2-8 in sequence, and using the drilling rig to perform atmospheric pressure water construction drilling to a designated position according to a design scheme of hole drilling construction, without retracting the drill pipe after the hole drilling construction is completed; [0037] b. Device connection. Using the ultra-high pressure hose 1-2 to match and communicate the ultra-high pressure clean water pump 1-1 with the ultra-high pressure rotary water swivel 1-3; connecting the ultra-high pressure rotary water swivel 1-3 with the abrasive rotary sealing water swivel 2-5, and then installing the two on the double-channel sealing drill pipe 2-6; using the abrasive transfer hose 2-4 to match and communicate the abrasive rotary sealing water swivel 2-5 with the abrasive tank 2-1. [0038] c. Cutting construction. First, opening the pressure cap 2-3 before abrasive jet cutting, adding abrasive sand and water to the abrasive tank 2-1 at a sand-to-water ratio of 2:1, and tightening the pressure cap 2-3 after the abrasive is fully filled. Then, starting the ultra-high pressure clean water pump 1-1, adjusting the pressure to 30 MPa to conduct a pressure adjusting test, and increasing the pressure slowly. After returned water at the opening of a hole is normal, starting the feeding pump and increasing the pressure to 15 MPa. After the pressure of the filling pump is stable, adjusting the pressure of the ultra-high pressure clean water pump 1-1 to 60-100 MPa to perform abrasive jet cutting, and keeping the pressure for 10-15 min. After single knife cutting is completed, turning off the feeding pump, reducing the pressure of the ultra-high pressure clean water pump 1-1 to 5 MPa, and keeping the pressure for 2-3 min. After returned water at the opening of a drilled hole is normal, turning off the ultra-high pressure clean water pump 1-1. Retracting the drill pipe from the hole, and following the above steps in sequence to complete hole drilling and cutting operations. [0039] d. Device cleaning. After hole drilling and cutting are completed, injecting clean water into the abrasive tank 2-1 and tightening the pressure cap 2-3. Then, starting the feeding pump, increasing the pressure to 5 MPa and keeping the pressure for 2 min; cleaning the residual abrasive in the abrasive tank 2-1, the abrasive rotary sealing water swivel 2-5, the double-channel sealing drill pipe 2-6 and the double-channel cutter 2-7. After cleaning, turning off the feeding pump. Removing various components in sequence, placing the components in designated positions to be kept properly, and thus ending the cutting operation.

[0040] Finally, it should be noted that the above embodiments are only used for describing, rather than limiting the technical solution of the present invention. Although the present invention is described in detail with reference to the preferred embodiments, those ordinary skilled in the art shall understand that the technical solution of the present invention can be amended or equivalently replaced without departing from the purpose and the scope of the technical solution. The amendment or equivalent replacement shall be covered within the scope of the claims of the present invention.