CN211679172U - Dredging system for drilling mud tank - Google Patents

Abstract

The utility model provides a well drilling mud jar desilting system. The hose pump positively rotates to suck clean water in the liquid phase storage tank A bin and pumps the clean water into the desilting crushing head to form high-pressure water jet, the sludge body at the bottom of the mud tank is directly hydraulically crushed, the high-pressure water jet drives the desilting crushing head to mechanically cut and crush the sludge body at the bottom of the mud tank, the sludge body is crushed and then is stirred and mixed with the clean water to form a pumpable solid-liquid mixture, the hose pump reversely rotates to discharge the solid-liquid mixture into the liquid phase storage tank B bin, the solid-liquid mixture is centrifugally dewatered and dried by the high-speed centrifuge, the treated clean water returns to the liquid phase storage tank A bin, and the separated solid phase is discharged into the solid phase. The utility model discloses can accomplish the broken, transport of well drilling mud tank siltation body and take off the liquid mummification, solve the artifical desilting work load of well drilling mud tank bottoms big, the limited and not environmental protection problem of silt emission in operation space, improve clear jar efficiency, simple structure, convenient operation, degree of automation is high.

Description

Dredging system for drilling mud tank

Technical Field

The utility model relates to a well drilling engineering technique and the well drilling ground equipment of equipping the field, especially a well drilling mud tank desilting system.

Background

The mud tank is one of necessary equipment for drilling, and is mainly used for storing and conveying mud, in the process of petroleum drilling, after solid-liquid mixture containing rock debris returning from the bottom of a well is treated by purification equipment, most of the rock debris is removed, but a small part of the rock debris remains and is deposited in the mud tank to form a relatively hard deposition body, along with the lapse of drilling time, the deposition body in the tank is larger and larger, and is hardened and hard, the volume of the tank and the mud performance are influenced, and the volume of the tank and the mud performance account for about one third or even half of the volume of the mud tank, so that the volume of the mud tank is reduced, the mud performance is unstable, and the weight of the mud tank is increased.

Therefore, the tank cleaning is needed after one well is completed and before equipment is moved, and the tank cleaning is increased for 1-2 times even in the midway process of drilling one well. The method that at present generally adopts is that the manual work gets into from mud tank top, utilizes instrument such as spade to break the siltation body of deposiing and digs out, and reuse spade shovels out to ground or mud pit from the sand discharge door, especially can appear serious sediment phenomenon along with the well drilling time extension or heavy phase and detritus in the mud tank pouring process and when standing for a long time, and sedimentary siltation body thickness is bigger and bigger, causes mud tank's sand discharge door can't open, can only lift the tank face with the bucket by the manual work and empty.

The general well team has 4-5 50m³The mud tank needs 5-6 people for one-time manual tank cleaning operation, the tank cleaning time is about 24-48 hours, the time for difficult cleaning and necessary dredging is even longer, pungent mud pharmaceutical chemical material smell is diffused in the tank during tank cleaning, toxic and harmful hydrogen sulfide is also accompanied in the stratum of some areas and enters the mud tank along with drilling fluid, the harm to the health of human bodies is great, the mud tank can work only by wearing a gas mask, personnel can not work in the tank for a long time, but alternately enter the tank for operation, the tank cleaning time is long, the work is heavy, the labor intensity is high, the efficiency is low, and the health of workers and the safety work of a drilling crew are influenced.

For sludge deposited in a less hard sludge tank, a high-pressure water gun is adopted to puncture the deposited sludge in the sludge tank, and the sludge is diluted and scattered and then discharged into a sludge tank through a tank bottom sand discharge door. With the improvement of the environmental protection requirement of oil field drilling, the whole drilling and completion process adopts a mud non-landing mode, a mud pit with certain environmental pollution hidden trouble is not reserved any more, and the method for discharging sediments in the mud tank by using the high-pressure water gun is not practicable.

Therefore, the existing dredging and discharging modes of the drilling mud tank are seriously not in line with the requirements of health, safety and environmental protection, and the necessary trends are to replace manual dredging, improve the mud tank and treat the sludge body in an environmental protection way.

The utility model discloses the technical scheme who creates the air pressure cleaning device of "mud jar deposit" (the authorized bulletin number "CN 207271739U) and publish adopts corresponding pipe fitting combination, and sediment in the suction tank is discharged and is handled once more in the holding vessel, including air supply, storage tank and vacuum pump, and the device simple structure is nevertheless not good to the sediment treatment effect that has hardened.

The utility model discloses create the technical scheme that the name "mud jar can cleaning device" (authorized bulletin number "CN 204553866U") promulgated is that research and development seals reliable valve member, solves jar side bottom sand removal door or butterfly valve, and the waste liquid in-process of discharging, sand removal door or butterfly valve are sealed effectual, leak easily and the problem that splashes. However, the device is suitable for a mode of directly discharging the slurry into a slurry pool, and the slurry applied at the current stage cannot fall to the ground for construction, and cannot be used without the slurry pool on the site.

The utility model provides an automatic mud tank of decontaminating (the license number "CN 206529391U") the technical scheme who publishes adopts the mud tank body and sets up power device, the device that rises to become silted up, arrange silt device, washing unit in the mud tank body; the silt device that rises includes linear guide and plays the silt shell, plays the silt shell and installs on linear guide, installs rotatory impeller in playing the silt shell to in a cycle period with the sediment silt clearance and the timely discharge of mud tank body bottom, can stir the mud in the mud tank body, alleviate the phenomenon that the mud tank body sinks the silt, this technique is applicable to and installs and reform transform the jar when newly building the jar, only is applicable to under the sedimentation initial stage does not have the sclerosis condition, and the suitability is relatively poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a drilling mud tank desilting system for solving the above-mentioned problem that drilling mud tank bottoms desilting exists, avoid artifical desilting operation risk in the enclosure space, utilize high-pressure water jet and mechanical system to collapse broken silting volume, clear away the deposit in the mud tank to dewater and spin-dry to it, clear solution recycle after the processing reduces clear tank personnel intensity of labour and activity duration, improves the construction security.

In order to solve the above problems, the technical solution of the present invention is:

a dredging system of a drilling mud tank comprises a stirrer A51, a mud tank 50, a pipeline A49, a liquid phase storage tank 34, a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a solid phase collection tank 43, a pipeline D45 and a dredging crushing head 46; wherein:

a stirrer A51 is arranged on the mud tank 2, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42 and a hose pump control cabinet 44 are arranged on the tank surface of the liquid phase storage tank 34;

the liquid phase storage tank 34 is divided into an A bin 47 and a B bin 48 which are not communicated, the A bin 47 stores clear water or clear liquid, and the B bin 48 collects and stores sludge bodies of the sludge tank, and the sludge bodies are crushed and then stirred and mixed with the clear water to form a pumpable solid-liquid mixture; a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a hose pump control cabinet 44 and a pipeline D45 are arranged on the tank surface of the liquid phase storage tank 34, and a solid phase collection tank 43 is used for temporarily storing a solid phase separated by the high-speed centrifuge 42;

one end of the pipeline A49 is connected with the pipeline interface at the upper part of the hose pump 39, and the other end is connected with the desilting crushing head 46; one end of the pipeline B35 is connected with a pipeline connector at the lower part of the hose pump 39, the other end of the pipeline B35 extends into the bottom of the A bin 47 of the liquid phase storage tank 34, and the pipeline B35 is provided with a valve 36; one end of a pipeline C37 is connected with a pipeline B35 at the pipeline interface at the lower part of the hose pump 39, a valve 38 is arranged, and the other end of the pipeline C37 extends into the bottom of the B bin 48 of the liquid phase storage tank 34; one end of a pipeline D45 is connected with a liquid outlet of the high-speed centrifuge 42, and the other end is connected into the A bin 47 of the liquid phase storage tank 34;

the dredging crushing head 46 comprises a shell 23 and a reamer disk 1; the hose pump control cabinet 44 controls the start, normal rotation, reverse rotation, and stop of the hose pump 39.

The above scheme further comprises:

a liquid inlet 24 is arranged at the connecting end of a shell 23 of the dredging crushing head, a plurality of axial straight nozzles 30 which are circumferentially distributed at intervals are arranged on the front end surface of the shell 23, a radial inclined nozzle 31 and a shaft seat are arranged at the periphery of the shell 23 corresponding to the axial straight nozzles 30, and the axial straight nozzles 30 and the radial inclined nozzle 31 are communicated with the liquid inlet 24 through a flow passage 29; the cutterhead 1 corresponds to the shaft seat, each cutterhead 1 is installed in the shaft seat of the shell 23 through a cutterhead shaft 3 and a shaft seat assembly, cutting blades are arranged on the cutterhead 1, a plurality of rotor blades 2 are circumferentially arranged on the cutterhead shaft 3 at equal intervals, and the positions of the blades 2 are opposite to the radial inclined nozzles 31.

The casing 23 is of a hollow structure, a valve core 19 is arranged in the casing, a radial hole 25 and an axial hole 26 on the valve core are arranged on the valve core 19, a valve seat, a central cavity 27, a radial hole 28 and a flow channel 29 on the casing are arranged in the casing 23, the liquid inlet 24 is sequentially communicated with the axial hole 26, the radial hole 25 on the valve core, the central cavity 27, the radial hole 28 on the casing, the flow channel 29, an axial straight nozzle 30 and a radial inclined nozzle 31, and the front end face of the valve core 19 is in dynamic sealing fit with the valve seat.

The axle seat assembly comprises: the shaft 17 is supported in a shaft seat of the shell 23 through a back-to-back double bearing 10 and is fixed on the shaft seat at the periphery of the shell 23 through a connecting bolt A4, a throttling annular sealing cover A5, a framework oil seal A6, a spacer ring 7, a framework oil seal B8, an oil seal box 9, an O-shaped rubber sealing ring 12, a shaft sleeve 13, a throttling annular sealing cover B14, an end cover 15 and a connecting bolt B16; the reamer shafts 3 on each set of cutterheads 1 are connected to a shaft 17.

The back-to-back duplex bearing 10 is sealed by a bidirectional sealing structure combining mechanical dynamic seal and static seal, and a lubricant is injected and lubricated by the straight-through type pressure injection oil cup 11.

The quantity of the cutterheads 1 is three, the three groups of cutterheads 1 are annularly arranged on the periphery of the shell 23 at equal intervals, and each group of cutterheads 1 is provided with three cutting blades which are uniformly arranged.

5-8 annular rotor blades 2 which are arranged axially at equal intervals are arranged on the reamer shaft 3.

A spring 20 is also included, the spring 20 urging the poppet 19 against a poppet-to-seat contact surface 32 within the housing 23.

And a protective cover is arranged on the outer periphery of the cutterhead 1.

Compared with the prior art, the beneficial effects of the utility model are that: (1) the mud tank dredging and the environment-friendly treatment of the mud can be completed, the risk of manual tank cleaning operation in a closed space is solved, the tank cleaning efficiency is improved, and the requirements of health, safety and environment protection are met. (2) The use cost is low, and the drilling expense is obviously saved. (3) Simple structure, convenient operation, degree of automation is high.

Drawings

Fig. 1 is the overall structure schematic diagram of the dredging crushing head of the utility model.

Fig. 2 is a cross-sectional view taken along line a-a of fig. 1.

FIG. 3 is an enlarged schematic view of the reamer shaft bearing assembly of FIG. 1.

Fig. 4 is the schematic structural diagram of the dredging system of the drilling mud tank of the utility model.

Reference numerals:

1. a cutterhead; 2. a rotor blade; 3. a reamer shaft; 4. a connecting bolt A; 5. a throttling annular sealing cover A; 6. a framework oil seal A; 7. a spacer ring; 8. a framework oil seal B; 9. an oil seal box; 10. back-to-back duplex bearings; 11. a straight-through type pressure injection oil cup; 12. an O-shaped rubber sealing ring; 13. a shaft sleeve; 14. a throttling annular sealing cover B; 15. an end cap; 16. a connecting bolt B; 17. a shaft; 18. plugging the bolt; 19. A valve core; 20. a spring; 21. a circlip for a hole; 22. a spring cover plate; 23. a housing; 24. a liquid inlet; 25. a radial bore in the spool; 26. an axial bore in the valve core; 27. a central bore of the housing; 28. a radial bore of the housing; 29. an axial flow passage inside the housing; 30. an axial straight nozzle; 31. a radially inclined nozzle; 32. the contact surface of the valve core and the valve seat; 33. an outlet; 34. a liquid phase storage tank; 35. a line B; 36. a valve A; 37. a line C; 38. a valve B; 39. a hose pump; 40. a stirrer B; 41. a slurry pump; 42. a high speed centrifuge; 43. a solid phase collection tank; 44. a hose pump control cabinet; 45. a line D; 46. dredging the crushing head; 47. a, storing in a warehouse; 48. b, a cabin; 49. a line A; 50. A mud tank; 51. and a stirrer A.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Example 4

Referring to fig. 1, a dredging system of a drilling mud tank comprises a stirrer A51, a mud tank 50, a pipeline A49, a liquid phase storage tank 34, a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a solid phase collection tank 43, a pipeline D45 and a dredging crushing head 46; wherein:

a stirrer A51 is arranged on the mud tank 2, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42 and a hose pump control cabinet 44 are arranged on the tank surface of the liquid phase storage tank 34;

the liquid phase storage tank 34 is divided into an A bin 47 and a B bin 48 which are not communicated, the A bin 47 stores clear water or clear liquid, and the B bin 48 collects and stores sludge bodies of the sludge tank, and the sludge bodies are crushed and then stirred and mixed with the clear water to form a pumpable solid-liquid mixture; a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a hose pump control cabinet 44 and a pipeline D45 are arranged on the tank surface of the liquid phase storage tank 34, and a solid phase collection tank 43 is used for temporarily storing a solid phase separated by the high-speed centrifuge 42;

one end of the pipeline A49 is connected with the pipeline interface at the upper part of the hose pump 39, and the other end is connected with the desilting crushing head 46; one end of the pipeline B35 is connected with a pipeline connector at the lower part of the hose pump 39, the other end of the pipeline B35 extends into the bottom of the A bin 47 of the liquid phase storage tank 34, and the pipeline B35 is provided with a valve 36; one end of a pipeline C37 is connected with a pipeline B35 at the pipeline interface at the lower part of the hose pump 39, a valve 38 is arranged, and the other end of the pipeline C37 extends into the bottom of the B bin 48 of the liquid phase storage tank 34; one end of a pipeline D45 is connected with a liquid outlet of the high-speed centrifuge 42, and the other end is connected into the A bin 47 of the liquid phase storage tank 34;

the dredging crushing head 46 comprises a shell 23 and a reamer disk 1; the hose pump control cabinet 44 controls the start, normal rotation, reverse rotation, and stop of the hose pump 39.

Example 2

Referring to the attached fig. 1-3, a dredging crushing head of a dredging system of a drilling mud tank, a liquid inlet 24 is arranged at the connecting end of a shell 23, a plurality of axial straight nozzles 30 distributed at intervals in the circumferential direction are arranged on the front end surface of the shell 23, a radial inclined nozzle 31 and a shaft seat are arranged at the outer periphery of the shell 23 corresponding to the axial straight nozzles 30, and the axial straight nozzles 30 and the radial inclined nozzle 31 are communicated with the liquid inlet 24 through a flow passage 29; the cutterhead 1 corresponds to the shaft seat, each cutterhead 1 is installed in the shaft seat of the shell 23 through a cutterhead shaft 3 and a shaft seat assembly, cutting blades are arranged on the cutterhead 1, a plurality of rotor blades 2 are circumferentially arranged on the cutterhead shaft 3 at equal intervals, and the positions of the blades 2 are opposite to the radial inclined nozzles 31.

The casing 23 is of a hollow structure, a valve core 19 is arranged in the casing, a radial hole 25 and an axial hole 26 are formed in the valve core 19, a valve seat, a central cavity 27, a radial hole 28 and a flow channel 29 are arranged in the casing 23, a liquid inlet 24 is sequentially communicated with the axial hole 26, the radial hole 25, the central cavity 27, the radial hole 28, the flow channel 29, an axial straight nozzle 30 and a radial inclined nozzle 31, and the front end face of the valve core 19 is in dynamic sealing fit with the valve seat.

The axle seat assembly comprises: the shaft 17 is supported in a shaft seat of the shell 23 through a back-to-back double bearing 10 and is fixed on the shaft seat at the periphery of the shell 23 through a connecting bolt A4, a throttling annular sealing cover A5, a framework oil seal A6, a spacer ring 7, a framework oil seal B8, an oil seal box 9, an O-shaped rubber sealing ring 12, a shaft sleeve 13, a throttling annular sealing cover B14, an end cover 15 and a connecting bolt B16; the reamer shafts 3 on each set of cutterheads 1 are connected to a shaft 17.

The back-to-back duplex bearing 10 is sealed by a bidirectional sealing structure combining mechanical dynamic seal and static seal, and a lubricant is injected and lubricated by the straight-through type pressure injection oil cup 11.

The quantity of the cutterheads 1 is three, the three groups of cutterheads 1 are annularly arranged on the periphery of the shell 23 at equal intervals, and each group of cutterheads 1 is provided with three cutting blades which are uniformly arranged.

5-8 annular rotor blades 2 which are arranged axially at equal intervals are arranged on the reamer shaft 3.

A spring 20 is also included, the spring 20 urging the poppet 19 against a poppet-to-seat contact surface 32 within the housing 23.

And a protective cover is arranged on the outer periphery of the cutterhead 1.

Exemplary embodiment 3

Referring to fig. 1, a dredging system of a drilling mud tank comprises a stirrer A51, a mud tank 50, a pipeline A49, a liquid phase storage tank 34, a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a solid phase collection tank 43, a hose pump control cabinet 44, a pipeline D45 and a dredging crushing head 46.

The slurry tank 50 is provided with a stirrer A51, and the liquid phase storage tank 34 is provided with a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42 and a hose pump control cabinet 44 on the tank surface.

The liquid phase storage tank 34 is divided into an A bin 47 and a B bin 48 which are not communicated, the A bin 47 stores clear water or clear liquid, and the B bin 48 collects and stores sludge bodies of the sludge tank, and the sludge bodies are crushed and then stirred and mixed with the clear water to form a pumpable solid-liquid mixture; the liquid phase storage tank 4 is provided with a pipeline B35, a valve A36, a pipeline C37, a valve B38, a hose pump 39, a stirrer B40, a slurry pump 41, a high-speed centrifuge 42, a hose pump control cabinet 44 and a pipeline D45 on the tank surface, and a solid phase collection tank 43 is used for temporarily storing solid phase separated by the high-speed centrifuge 42.

One end of the pipeline A49 is connected with the pipeline interface at the upper part of the hose pump 39, and the other end is connected with the desilting crushing head 46; one end of the pipeline B35 is connected with a pipeline connector at the lower part of the hose pump 39, the other end of the pipeline B35 extends into the bottom of the A bin 47 of the liquid phase storage tank 34, and the pipeline B35 is provided with a valve 36; one end of a pipeline C37 is connected with a pipeline B35 at the pipeline interface at the lower part of the hose pump 39, a valve 38 is arranged, and the other end of the pipeline C37 extends into the bottom of the B bin 48 of the liquid phase storage tank 34; one end of the pipeline D45 is connected with the liquid outlet of the high-speed centrifuge 42, and the other end is connected into the A bin 47 of the liquid phase storage tank 34.

The front end of the dredging crushing head 46 is provided with a blade and a reamer disk, and under the action of high-pressure water jet, the blade is driven to rotate so as to drive the reamer disk on the dredging crushing head 46 to rotate and cut, so as to cut a sludge body at the bottom of the sludge tank 50; the hose pump control cabinet 44 controls the start, normal rotation, reverse rotation, and stop of the hose pump 39.

The utility model discloses a theory of operation is: the hose pump control cabinet 44 is started, so that the hose pump 39 positively rotates to suck clear water in the A bin 47 of the liquid phase storage tank 34 and pumps the clear water into the dredging crushing head 46 to form high-pressure water jet, one part of the high-pressure water jet directly and hydraulically crushes the sludge body at the bottom of the mud tank 50, the other part of the high-pressure water jet is used as power to drive the dredging crushing head 46 to mechanically cut and crush the sludge body at the bottom of the mud tank 50, and the crushed sludge body is stirred and mixed with the clear water to form a pumpable solid-liquid mixture. The switch on the hose pump control cabinet 44 is switched to enable the hose pump 39 to reversely rotate, and the solid-liquid mixture is discharged into the bin B of the liquid phase storage tank 34 and then subjected to centrifugal liquid removal drying treatment by the high-speed centrifuge 42. The treated clean water returns to the A cabin of the liquid phase storage tank 34, and the solid phase separated after the liquid removal and drying is discharged into the solid phase collection tank 43.

A dredging method of a drilling mud tank based on a dredging system of the drilling mud tank comprises the following steps:

first, open valve a36 on line B35, close valve B38 on line C37; the hose pump control cabinet 44 is controlled to rotate the hose pump 39 forwards, clean water in the bin A47 of the liquid-phase storage tank 34 is sucked in through the pipeline B35, and under the pumping action of the hose pump 39, the clean water is pumped into the desilting crushing head 46 through the pipeline A49 to form high-pressure water jet; one part of the high-pressure water jet directly and hydraulically crushes the sludge body at the bottom of the mud tank 50, and the other part of the high-pressure water jet is used as power to drive blades on the dredging crushing head 46 to rotate, so that the sludge body at the bottom of the mud tank is mechanically cut and crushed; dragging the dredging and crushing head 46 and the pipeline A49 to comprehensively crush all sludge in the sludge tank 50;

secondly, the hose pump control cabinet 44 is controlled to stop the hose pump 39, the stirrer A51 is started to work, and the crushed mud sediment and clean water are stirred and mixed to form a pumpable solid-liquid mixture;

thirdly, closing a valve A36 on a pipeline B35, opening a valve B38 on a pipeline C37, operating a hose pump control cabinet 44 to enable a hose pump 39 to reversely rotate, sucking a solid-liquid mixture in a slurry tank 50 into the hose pump 39 through a desilting crushing head 46 and the pipeline A49, and discharging the solid-liquid mixture into a B bin 48 of a liquid phase storage tank 34 through a pipeline C37;

and fourthly, starting the stirrer B40, the high-speed centrifuge 42 and the slurry pump 41 to work in sequence, pumping the solid-liquid mixture in the B bin 48 into the high-speed centrifuge 42 for dehydration and separation, discharging the solid phase separated by dehydration into the solid phase collecting tank 43, and returning the clear water after dehydration and separation into the A bin 47 of the liquid phase storage tank 34 through a pipeline D45 for next desilting cycle.

The utility model has the advantages that: can accomplish well drilling mud jar siltation body breakage automatically, carry and take off the liquid mummification, the utility model discloses a high-pressure fluid carries out hydraulic fracture and mechanical cutting simultaneously and smashes the hard siltation body of well drilling mud tank bottoms, it is big to solve the artifical desilting work load of well drilling mud tank bottoms, high in labor strength, not environmental protection, unhealthy, dangerous and there are the restricted and volatile gaseous harmful scheduling problem to the human body of working space, can avoid artifical clear jar operation risk in the enclosure space, improve clear jar efficiency, the operation is simple, convenient, swiftly, easily integrated supporting, the installation is dismantled and is maintained, low in use cost, degree of automation is high, has good economy, practicality, security and feature of environmental protection.

Claims (9)

1. A dredging system of a drilling mud tank comprises a stirrer A (51), a mud tank (50), a pipeline A (49), a liquid phase storage tank (34), a pipeline B (35), a valve A (36), a pipeline C (37), a valve B (38), a hose pump (39), a stirrer B (40), a slurry pump (41), a high-speed centrifuge (42), a solid phase collection tank (43), a pipeline D (45) and a dredging crushing head (46); the method is characterized in that:

a stirrer A (51) is arranged on the mud tank (50), and a hose pump (39), a stirrer B (40), a slurry pump (41), a high-speed centrifuge (42) and a hose pump control cabinet (44) are arranged on the tank surface of the liquid-phase storage tank (34);

the liquid phase storage tank (34) is divided into an A bin (47) and a B bin (48) which are not communicated, the A bin (47) stores clear water or clear liquid, and the B bin (48) collects, stores and crushes sludge bodies of the mud tank, and then stirs and mixes the crushed sludge bodies with the clear water to form a pumpable solid-liquid mixture; a pipeline B (35), a valve A (36), a pipeline C (37), a valve B (38), a hose pump (39), a stirrer B (40), a slurry pump (41), a high-speed centrifuge (42), a hose pump control cabinet (44) and a pipeline D (45) are arranged on the tank surface of the liquid phase storage tank (34), and a solid phase collection tank (43) is used for temporarily storing a solid phase separated by the high-speed centrifuge (42);

one end of the pipeline A (49) is connected with a pipeline interface at the upper part of the hose pump (39), and the other end is connected with the desilting crushing head (46); one end of the pipeline B (35) is connected with a pipeline interface at the lower part of the hose pump (39), the other end of the pipeline B (35) extends into the bottom of the A bin (47) of the liquid phase storage tank (34), and a valve A (36) is arranged on the pipeline B (35); one end of a pipeline C (37) is connected to a pipeline B (35) at a pipeline interface at the lower part of the hose pump (39), a valve B (38) is installed, and the other end of the pipeline C (37) extends into the bottom of a tank B (48) of the liquid phase storage tank (34); one end of a pipeline D (45) is connected with a liquid outlet of the high-speed centrifuge (42), and the other end is connected into a bin A (47) of the liquid phase storage tank (34);

the dredging crushing head (46) comprises a shell (23) and a cutterhead (1); a hose pump control cabinet (44) controls the starting, forward rotation, reverse rotation, and stopping of the hose pump (39).

2. The drilling mud tank desilting system of claim 1, wherein: a liquid inlet (24) is arranged at the connecting end of a shell (23) of the dredging crushing head, a plurality of axial straight nozzles (30) which are circumferentially distributed at intervals are arranged on the front end surface of the shell (23), a radial inclined nozzle (31) and a shaft seat are arranged on the outer periphery of the shell (23) corresponding to the axial straight nozzles (30), and the axial straight nozzles (30) and the radial inclined nozzle (31) are communicated with the liquid inlet (24) through a flow passage (29); the reamer heads (1) correspond to the shaft seats, each reamer head (1) is installed in the shaft seat of the shell (23) through a reamer shaft (3) and the shaft seat assembly, cutting blades are arranged on the reamer heads (1), a plurality of rotor blades (2) are circumferentially arranged on the reamer shaft (3) at equal intervals, and the positions of the blades (2) are opposite to the radial inclined nozzles (31).

3. The drilling mud tank desilting system of claim 2, wherein: the shell (23) is of a hollow structure, a valve core (19) is arranged in the shell, a radial hole (25) and an axial hole (26) in the valve core are formed in the valve core (19), a valve seat, a central cavity (27), a radial hole (28) and a flow channel (29) in the shell are arranged in the shell (23), the liquid inlet (24) is sequentially communicated with the axial hole (26), the radial hole (25) in the valve core, the central cavity (27), the radial hole (28) in the shell, the flow channel (29), an axial straight nozzle (30) and a radial inclined nozzle (31), and the front end face of the valve core (19) is in dynamic sealing fit with the valve seat.

4. The drilling mud tank desilting system of claim 3, wherein: the axle seat assembly comprises: the shaft (17) is supported in a shaft seat of the shell (23) through back-to-back double bearings (10) and is fixed on the shaft seat at the periphery of the shell (23) through a connecting bolt A (4), a throttling annular sealing cover A (5), a framework oil seal A (6), a spacer ring (7), a framework oil seal B (8), an oil seal box (9), an O-shaped rubber sealing ring (12), a shaft sleeve (13), a throttling annular sealing cover B (14), an end cover (15) and a connecting bolt B (16); the reamer shafts (3) on each set of cutterheads (1) are connected to a shaft (17).

5. The drilling mud tank desilting system of claim 4, wherein: the back-to-back duplex bearing (10) is sealed by a bidirectional sealing structure combining mechanical dynamic seal and static seal, and a lubricant is injected and lubricated by the straight-through type pressure injection oil cup (11).

6. A drilling mud tank dredging system according to any one of claims 2-5, characterized in that: the quantity of the cutterheads (1) is three, the three groups of cutterheads (1) are annularly and equidistantly arranged on the periphery of the shell (23), and three cutting blades are uniformly arranged on each group of cutterheads (1).

7. A drilling mud tank dredging system according to any one of claims 2-5, characterized in that: 5-8 annular rotor blades (2) which are arranged axially at equal intervals are arranged on the reamer shaft (3).

8. A drilling mud tank dredging system according to any one of claims 2-5, characterized in that: the valve core (19) is pressed on a valve core and valve seat contact surface (32) in the shell (23) by the spring (20).

9. A drilling mud tank dredging system according to any one of claims 2-5, characterized in that: the outer periphery of the cutterhead (1) is provided with a protective cover.

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