CN212215359U - High-speed water hammer composite overweight mechanism - Google Patents

Abstract

The utility model discloses a compound overweight mechanism of high-speed water hammer, including a stator section of thick bamboo and rotor, the dabber of rotor passes through bearing and bearing frame seal support in a stator section of thick bamboo, be provided with impeller group and overweight bed in the spindle, be provided with the spacer ring that is used for sealed isolation in the middle of the stator section of thick bamboo, the spacer ring keeps apart impeller group and overweight bed and cuts apart a stator section of thick bamboo for stirring chamber and overweight chamber, a stator section of thick bamboo is provided with the input port that is used for the feeding on the lateral wall in stirring chamber, a stator section of thick bamboo is provided with the delivery outlet that is used for the ejection of compact on the lateral wall in overweight chamber, the one end of dabber in a stator section of thick bamboo is provided with the dabber intercommunication punch combination that is used. The utility model discloses compound overweight mechanism of high-speed water hammer accomplishes indissolvable solvent solution preparation, macroscopic mixing, microcosmic dissolving and can reduce the volume of equipment when the molecule infiltration curing, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency.

Description

High-speed water hammer composite overweight mechanism

Technical Field

The utility model relates to a petrochemical equipment technical field especially relates to a compound overweight mechanism of high-speed water hammer.

Background

The original technology for preparing, dissolving and curing the injection agent for land tertiary oil recovery, intelligent energy gathering and oil displacement has too long process, more equipment and large floor area, for example 50m for daily preparation³The high-concentration mother liquor occupies an area of 200m²Above, several hundred meters³The occupied area for preparing the mother solution is larger. Long flow, more equipment, more machine sets, high power consumption, high management and maintenance difficulty and the like. StoreThe occupied space is large, and the field is large.

In the prior art, the injection flow of the intelligent energy-gathering oil displacement agent of an oil field injection system is shown in the attached figure 1, and the solution of the intelligent energy-gathering oil displacement agent is prepared: the high-pressure water supplied by the intelligent energy-gathering oil displacement agent in the intelligent energy-gathering agent hopper 2 'and the water inlet valve 1' is fed into the solid-liquid mixer 3 'according to the proportion for preliminary mixing and dispersion, and then is output to the buffer tank 4' for stirring for 1-4 hours, so that the intelligent energy-gathering oil displacement agent is uniformly dispersed into the water, the solvent is not agglomerated and fish eyes do not appear, and the high-concentration mixed mother liquor is prepared.

Mother liquor storage and curing: the mixed mother liquor is led to a curing tank 5' for curing. The molecules of the intelligent energy gathering agent are in a coil structure, and gradually swell in an aqueous solution, so that the viscosity of the solution rises, and the swelled solution is not easy to block an oil layer. The curing time of the smart concentrator solution is generally set to be 18-240 h. The curing tank 5' occupies large area and space volume, and has long curing time and low efficiency.

Diluting and pumping: the concentration of the mother liquor is generally 5000mg/L, and the mother liquor is diluted after being cured and then is injected into an oil layer below a wellhead device 7 'by using a booster pump 6'. The dilution water is typically sewage. The booster pump 6' is a plunger pump, the displacement of which is generally not more than 200m³And d, when the plunger pump is specially added with solid particles, the maintenance period of a pump valve and a high-pressure sealing packing is generally short.

The intelligent energy-gathering oil displacement agent solution preparation, mother solution storage and curing in the existing oilfield injection system have the disadvantages of long process, more equipment, more machine sets, high power consumption and high management and maintenance difficulty. The curing tank has the defects of large occupied area and space volume, long curing time, low efficiency and the like.

In the chemical field, aiming at indissolvable organic or inorganic solvents such as polymers, the existing preparation and curing process equipment also has the problems of long mixing, preparation and dissolving and curing period.

Therefore, there is a need to develop a high-speed water hammer composite overweight mechanism.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a compound overweight mechanism of high-speed water hammer accomplishes the volume that can reduce equipment when indissolvable solvent solution is prepared, macro mixing, dispersion, microcosmic dissolution and molecule infiltration curing, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency.

In order to solve the technical problem, the utility model adopts the following technical scheme:

the utility model relates to a compound overweight mechanism of high-speed water hammer, including a stator section of thick bamboo and rotor, the dabber of rotor passes through bearing and bearing frame seal support and is in the stator section of thick bamboo, be provided with impeller group and overweight bed on the dabber, be provided with the spacer ring that is used for sealed isolation in the middle of the stator section of thick bamboo, the spacer ring will impeller group and overweight bed are kept apart and are cut apart the stator section of thick bamboo is for stirring chamber and overweight chamber, a stator section of thick bamboo is in be provided with the input port that is used for the feeding on the lateral wall in stirring chamber, a stator section of thick bamboo is in be provided with the delivery outlet that is used for the ejection of compact on the lateral wall in overweight chamber, the dabber is in one end in the stator section of thick bamboo is provided with and is used for the intercommunication the dabber.

Further, the mandrel communicating hole group comprises a mandrel input hole, a mandrel output hole and a mandrel hole which are communicated with each other, the mandrel hole is coaxially arranged at the center of the shaft section of the mandrel in the stirring cavity and the overweight cavity, the mandrel input hole is arranged at the position, close to the spacer ring, of the mandrel in the stirring cavity along the radial direction, and the mandrel output hole is arranged at the position, close to the root of the overweight bed, of the mandrel along the radial direction.

Further, the bearing frame includes first bearing frame, second bearing frame and third bearing frame, two first bearing frame sets up respectively at both ends behind the bearing and support the bearing, the second bearing frame sets up overweight chamber outside, the second bearing frame through the internal diameter and the first sealing washer of external diameter department respectively sealed with clearance between dabber and the stator section of thick bamboo, third bearing frame sets up the stirring chamber outside, the second sealing washer of third bearing frame through internal diameter and external diameter department respectively sealed with clearance between dabber and the stator section of thick bamboo.

Furthermore, the centre of third bearing frame is provided with the annular groove, the input port corresponds the annular groove, the bottom of annular groove is provided with the orientation the low-pressure region input hole in stirring chamber.

Furthermore, the inside wall of third bearing frame with be provided with the spacer between the spacer ring, set up spoiler and the choking ring that is used for high-speed water hammer on the inside wall of spacer ring, increase high-speed water hammer effect.

Further, the impeller assembly comprises a pressurizing impeller unit and a stirring impeller unit which are axially connected in series.

Further, the channel gap of the overweight reaction bed of the overweight bed can be adjusted.

Furthermore, the stator barrel and the rotor are vertically arranged, the stirring cavity and the overweight cavity are vertically connected in series, and the top detecting end of the mandrel is in transmission connection with the driving unit.

Furthermore, the top in stirring chamber sets up the blast pipe that is used for the exhaust, stirring chamber below is provided with the material sieve of crossing, it filters from the stirring chamber enters into the mixed liquid in overweight chamber to cross the material sieve.

Compared with the prior art, the utility model discloses a beneficial technological effect:

the utility model relates to a high-speed water hammer composite overweight mechanism, which is characterized in that through a composite overweight mechanism mainly comprising a stator barrel and a rotor, an injected water source is pumped to the front of the composite overweight mechanism, mixed with an auxiliary agent to form a mixed solution, enters a stirring cavity through an input port, and is stirred at high speed through an impeller set, mixed macroscopically and dissolved microscopically; the super-heavy molecules enter the super-heavy cavity through the mandrel communicating hole group and are permeated, aged and filtered by the super-heavy molecules of the super-heavy bed. The utility model discloses compound overweight mechanism accomplishes intelligence and gathers solution preparation, mixture, dispersion, the volume that can reduce equipment when dissolving and curing of oil-displacing agent or other indissolvable solvents, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency.

In addition, the core shaft communicating hole group consisting of the core shaft input hole, the core shaft output hole and the core shaft hole is skillfully communicated with the stirring cavity and the overweight cavity, so that mixed liquid stirred and dispersed by the impeller group is output to the root of the overweight bed for overweight curing. Through the arrangement of the second bearing seat and the third bearing seat, a bearing cavity in which the bearing is arranged, a stirring cavity and an overweight cavity are conveniently isolated; through the setting of annular groove and low-pressure area input hole is convenient for introduce the mixed liquid that the input port introduced into the low-pressure area of stirring chamber, can form the negative pressure and adsorb the feeding, has saved the traditional mode of jet pump feeding. Set up spoiler and choking ring on the inside wall of spacer sleeve or stator section of thick bamboo, be convenient for hinder the mixed liquid that is stirred by the impeller high speed of impeller group, increase disturbance water hammer effect, be convenient for improve dissolving efficiency. Adjusting the curing degree, efficiency and dissolving uniformity of the curing liquid through the number, shape, rotating speed and parameters of the overweight bed; the solid-phase particle size of the curing liquid can be cut and controlled by adjusting the pores of the filler in the overweight reaction bed, and the filter of the system is replaced. The stator barrel and the rotor are vertically arranged, so that the installation floor area of the mechanism can be effectively reduced relative to the arrangement mode of a horizontal shaft, and the mechanism is suitable for application occasions with limited installation areas, such as offshore platforms of offshore oil fields.

Drawings

The present invention will be further explained with reference to the following description of the drawings.

FIG. 1 is a schematic diagram of an injection allocation flow of an intelligently gathered oil displacement agent of an oilfield injection system in the prior art;

fig. 2 is a schematic sectional view of a horizontal shaft of the high-speed water hammer composite overweight mechanism according to the embodiment of the present invention;

fig. 3 is a schematic sectional view of a vertical shaft of the high-speed water hammer composite overweight mechanism according to the embodiment of the present invention;

description of reference numerals: 1', an incoming water valve; 2', an intelligent energy gathering agent hopper; 3', a solid-liquid mixer; 4', a buffer tank; 5', a curing tank; 6', a booster pump; 7', a wellhead assembly;

1. a stator cartridge; 101. an input port; 102. a stirring chamber; 103. a superheavy chamber; 104. an output port; 105. an exhaust pipe; 2. a rotor; 201. a mandrel; 202. a mandrel input aperture; 203. a mandrel output aperture; 204. an impeller assembly; 205. an overweight bed; 206. an axis plug; 207. a shaft center hole; 208. sieving the materials; 3. a bearing; 4. a first bearing housing; 5. a second bearing housing; 501. a first seal ring; 6. a second bearing housing; 601. a second seal ring; 602. a low-voltage region input aperture; 7. a spacer sleeve; 8. a spacer ring; 9. a clamp spring; 10. an electric motor.

Detailed Description

The core of the utility model is to provide a compound overweight mechanism of high-speed water hammer accomplishes the volume that can reduce equipment when indissolvable solvent solution is prepared, macro mixing, dispersion, microcosmic dissolution and molecule infiltration curing, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency.

In the following, the technical solutions in the embodiments of the present invention will be clearly and completely described with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to the drawings, FIG. 1 is a schematic diagram of an injection allocation flow of an intelligently-gathered oil displacement agent of an oil field injection system in the prior art; fig. 2 is a schematic sectional view of a horizontal shaft of the high-speed water hammer composite overweight mechanism according to the embodiment of the present invention; fig. 3 is a schematic sectional view of a vertical shaft of the high-speed water hammer composite overweight mechanism according to the embodiment of the present invention.

In a specific embodiment, as shown in fig. 2, the high-speed water hammer composite overweight mechanism comprises a stator barrel 1 and a rotor 2, wherein a mandrel 201 of the rotor 2 is supported in the stator barrel 1 through a bearing 3 and a bearing seat in a sealing manner, and the stator barrel 1 is installed on a frame. The core shaft 201 is provided with an impeller group 204 and an overweight bed 205, the middle of the stator barrel 1 is provided with a spacer ring 8 for sealing and isolating, and the spacer ring 8 isolates the impeller group 204 and the overweight bed 205 and divides the stator barrel 1 into a stirring cavity 102 and an overweight cavity 103. An input port 101 for a mixed liquid of water, a main agent and an auxiliary agent is formed in the side wall of the stirring cavity 102 of the stator barrel 1, an output port 104 for outputting a cured mother liquid is formed in the side wall of the overweight cavity 103 of the stator barrel 1, a mandrel communicating hole group for communicating the stirring cavity 102 with the overweight cavity 103 is formed in one end, in the stator barrel 1, of the mandrel 201, and one end, extending out of the stator barrel 1, of the mandrel 201 is a power input end. The power input can adopt a motor direct drive or belt drive mode.

Through a composite overweight mechanism mainly composed of a stator barrel 1 and a rotor 2, an injected water source is pumped or sucked in front of the composite overweight mechanism under negative pressure, mixed with a main agent and an auxiliary agent sent out by a feeder to form a mixed solution, enters a stirring cavity 102 through an input port 101, and is subjected to high-speed stirring, macro-mixing and micro-dissolving by an impeller set 204; the composition of the communicating pores of the mandrel enters the overweight cavity 103 and is permeated, filtered and matured by overweight molecules in the overweight bed 205. The utility model discloses compound overweight mechanism volume reduces to less than 1 side reactor from 4 dispersion, curing jars total more than hundred, and the volume reduces more than hundred times, and the dissolution curing speed shortens to less than 10 minutes from 18-24 hours, raises the efficiency more than hundred times. Compared with the original stirring speed of 40-50 r/min, the stirring blades and the overweight bed are arranged on the high-speed rotating power shaft of 1000r/min in the embodiment, the acceleration is over ten thousand, and self-absorption feeding, high-speed water-hammer stirring, mixing and dissolving and overweight permeation, curing and filtering are realized. The utility model discloses compound overweight mechanism accomplishes intelligence and gathers solution preparation, mixture, dispersion, the volume that can reduce equipment when dissolving and curing of oil-displacing agent or other indissolvable solvents, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency.

In a specific embodiment of the present invention, as shown in fig. 2, the mandrel communicating hole group includes a mandrel input hole 202, a mandrel output hole 203 and a mandrel hole 207 which are communicated with each other, the mandrel hole 207 is coaxially disposed at the central position of the shaft section of the mandrel 201 located in the stirring chamber 102 and the overweight chamber 103, and the outer end of the mandrel hole 207 is sealed by the shaft plug 206 with a sealing ring. The mandrel input holes 202 are radially arranged at the position of the mandrel 201 close to the spacer ring 8 in the stirring cavity 102, and a plurality of mandrel input holes 202 are uniformly distributed on the circumference. The mandrel output holes 203 are radially arranged at the root part of the mandrel 201 in the overweight bed 205, and a plurality of groups of mandrel output holes 203 are uniformly distributed at the root part of the overweight bed 205 on the circumference and output the mixed liquid after stirring and dispersing to the overweight bed 205.

The stirring cavity 102 and the overweight cavity 103 are skillfully communicated through the mandrel communicating hole group consisting of the mandrel input hole 202, the mandrel output hole 203 and the mandrel hole 207, so that the mixed liquid stirred and dispersed by the impeller group 204 is output to the root of the overweight bed 205 for overweight curing.

The utility model discloses an in a specific embodiment, as shown in FIG. 2, the bearing frame includes first bearing frame 4, second bearing frame 5 and third bearing frame 6, two first bearing frame 4 set up respectively behind the bearing 3 at both ends and support bearing 3, second bearing frame 5 sets up in the overweight chamber 103 outside, second bearing frame 5 seals respectively through the first sealing washer 501 of internal diameter and external diameter department and dabber 201 and the clearance between the stator section of thick bamboo 1, third bearing frame 6 sets up in the stirring chamber 102 outside, third bearing frame 6 seals respectively through the second sealing washer 601 of internal diameter and external diameter department and seals the clearance between dabber 201 and the stator section of thick bamboo 1.

Specifically, as shown in fig. 2, the third bearing housing 6 is provided at the center thereof with an annular groove corresponding to the input port 101, and the bottom thereof is provided with a low pressure region input hole 602 toward the stirring chamber 102.

Specifically, as shown in fig. 2, a spacer 7 is disposed between an inner sidewall of the third bearing seat 6 and the spacer ring 8, and a flow blocking plate and a flow blocking ring for high-speed water hammer are disposed on the inner sidewall of the spacer 7, and are disposed around the outer periphery of the impeller assembly 204 to perform disturbance blocking on the liquid flow excited by the impeller assembly 204. Of course, when the spacer 7 is not provided, a spoiler and a spoiler ring may be correspondingly provided on the inner wall of the stator can 1.

The arrangement of the second bearing seat 5 and the third bearing seat 6 facilitates the isolation of the bearing chamber where the bearing 3 is located from the stirring chamber 102 and the overweight chamber 103; through the arrangement of the annular groove and the low-pressure area input hole 602, the mixed liquid introduced by the input port 101 is conveniently guided into the low-pressure area of the stirring cavity 102, negative pressure suction feeding can be formed, and the traditional feeding mode of a jet pump is saved. Through the setting of spacer 7, be convenient for guarantee the interval between the inside wall of third bearing frame 6 and the spacer ring 8, when changing the impeller quantity of impeller group 204, need change the spacer 7 of different length simultaneously, set up spoiler and choking ring on the inside wall of spacer 7, be convenient for hinder the mixed liquid that is stirred by the impeller of impeller group 204 at a high speed, increase disturbance water hammer effect, be convenient for improve dissolving efficiency.

In a specific embodiment of the present invention, as shown in fig. 2, the impeller assembly 204 includes a pressurizing impeller unit and a stirring impeller unit which are axially connected in series, and the impeller assembly pressure angle of the pressurizing impeller unit is located in the pressurizing pumping mixed liquid, and the negative pressure is formed at the low-pressure area input hole 602 to facilitate the suction-type feeding. And the number of the impellers of the supercharging impeller unit and the stirring impeller unit and the structural form of the impeller blades can be adjusted by replacing.

In one embodiment of the present invention, the gap between the channels of the overweight reaction bed of the overweight bed 205 can be adjusted by replacing the components of the overweight reaction bed. The micropores of the overweight reaction bed have the functions of homogenizing and filtering the curing liquid, and the filtering particle size phi of the flow passage is 0.15mm and the like which can be adjusted. The water hammer stirrer is coaxial with the overweight reaction bed, and the stirring overweight rotating speed is 300-970 r/min; the overweight acceleration is 200-1000 m/s2, and the rotating speed range can be properly adjusted according to the indissolvable degree of the solvent. Increasing the peripheral speed and the centrifugal force of the gravity reaction bed with the acceleration of 200-1000 m/s2 to ensure that the mixed liquid is rapidly dispersed, crushed and filmed in the filler in the overweight reaction bed, so that the constantly updated microelements are multiplied; the zigzag flow channel further aggravates the updating of the membrane interface of mass transfer and diffusion exchange and the rapid increase of the specific surface multiple; and pushes it towards the outer edge of the rotor. In the process, the liquid phase in the mixed liquid is in contact with the liquid phase in a solid-liquid mode under the conditions of high dispersion, high turbulence, strong mixing and interface rapid mass transfer exchange, so that the mixing, dissolving and curing efficiency is greatly enhanced.

Adjusting the curing degree, efficiency and dissolving uniformity of the curing liquid through the number, shape, rotating speed and parameters of the overweight bed; the solid-phase particle size of the curing liquid can be cut and controlled by adjusting the pores of the filler in the overweight reaction bed, and the filter of the system is replaced.

In a specific embodiment of the present invention, as shown in fig. 3, the stator tube 1 and the rotor 2 are vertically arranged, the mixing chamber 102 and the overweight chamber 103 are vertically connected in series, and the top of the mandrel 201 is connected to the driving unit through a transmission. The driving unit comprises a motor 10, the motor 10 is vertically installed on one side of the stator barrel 1, and an output shaft of the motor 10 is connected with a belt pulley which is connected with the top of the mandrel 201 through a transmission belt.

Specifically, as shown in fig. 3, an exhaust pipe 105 for exhausting air is arranged at the top of the stirring chamber 102, a baffle is added at the bottom of the exhaust pipe 105, and the exhaust pipe 105 is convenient for exhausting air mixed in during feeding; the material passing sieve 208 is arranged below the stirring cavity 102, the cylindrical material passing sieve 208 is sleeved on a mandrel input hole of the mandrel 201, the material passing sieve 208 filters mixed liquid entering the overweight cavity 103 from the stirring cavity 102, and the mixed liquid which is not fully macroscopically mixed and microscopically dissolved is prevented from entering the overweight cavity 103.

Through the vertical setting of stator section of thick bamboo 1 and rotor 2, can effectively reduce the installation area of this case mechanism for the arrangement mode of horizontal axis, be applicable to in installation area limited application occasions such as marine oil field offshore platform.

The utility model discloses compound overweight mechanism of high-speed water hammer through mainly comprising stator barrel 1 and rotor 2 compound overweight mechanism, and the water source of pouring into mixes into the mixed liquid with the auxiliary agent before the compound overweight mechanism is sent to through the pump sending, gets into stirring chamber 102 through input port 101 and through the high-speed stirring of impeller assembly 204, and the macro-mixing dissolves microscopically; the composition of the communicating pores of the mandrel enters the overweight cavity 103 and is permeated, filtered and matured by overweight molecules in the overweight bed 205. The utility model discloses compound overweight mechanism accomplishes intelligence and gathers solution preparation, mixture, dispersion, the volume that can reduce equipment when dissolving and curing of oil-displacing agent or other indissolvable solvents, reduces occupation space, improves simultaneously and dissolves curing process speed, improves production efficiency. In addition, the stirring cavity 102 and the overweight cavity 103 are skillfully communicated through the mandrel communicating hole group consisting of the mandrel input hole 202, the mandrel output hole 203 and the mandrel hole 207, so that the mixed liquid stirred and dispersed by the impeller group 204 is output to the root of the overweight bed 205 for overweight ripening. The arrangement of the second bearing seat 5 and the third bearing seat 6 facilitates the isolation of the bearing chamber where the bearing 3 is located from the stirring chamber 102 and the overweight chamber 103; through the arrangement of the annular groove and the low-pressure area input hole 602, the mixed liquid introduced by the input port 101 is conveniently guided into the low-pressure area of the stirring cavity 102, negative pressure suction feeding can be formed, and the traditional feeding mode of a jet pump is saved. The inner side wall of the spacer 7 or the stator barrel 1 is provided with the flow blocking plate and the flow blocking ring, so that mixed liquid stirred by the impellers of the impeller group 204 at a high speed is blocked, the water impact disturbing effect is increased, and the dissolving efficiency is improved. Adjusting the curing degree, efficiency and dissolving uniformity of the curing liquid through the number, shape, rotating speed and parameters of the overweight bed; the solid-phase particle size of the curing liquid can be cut and controlled by adjusting the pores of the filler in the overweight reaction bed, and the filter of the system is replaced. Through the vertical setting of stator section of thick bamboo 1 and rotor 2, can effectively reduce the installation area of this case mechanism for the arrangement mode of horizontal axis, be applicable to in installation area limited application occasions such as marine oil field offshore platform.

The above-mentioned embodiments are only intended to describe the preferred embodiments of the present invention, but not to limit the scope of the present invention, and various modifications and improvements made by those skilled in the art without departing from the design spirit of the present invention should fall into the protection scope defined by the claims of the present invention.

Claims (9)

1. A high-speed water hammer composite overweight mechanism is characterized in that: the centrifugal impeller comprises a stator barrel (1) and a rotor (2), wherein a mandrel (201) of the rotor (2) is supported in the stator barrel (1) through a bearing (3) and a bearing seat in a sealing manner, an impeller set (204) and an overweight bed (205) are arranged on the mandrel (201), a spacer ring (8) used for sealing and isolating is arranged in the middle of the stator barrel (1), the impeller set (204) and the overweight bed (205) are isolated and divided by the spacer ring (8), the stator barrel (1) is a stirring cavity (102) and an overweight cavity (103), an input port (101) used for feeding is arranged on the side wall of the stirring cavity (102) of the stator barrel (1), an output port (104) used for discharging is arranged on the side wall of the overweight cavity (103), one end of the mandrel (201) in the stator barrel (1) is provided with a hole group used for communicating the stirring cavity (102) with the overweight cavity (103), one end of the mandrel (201) extending out of the stator barrel (1) is a power input end.

2. The high-speed water hammer composite overweight mechanism of claim 1, characterized in that: the core shaft communicating hole group comprises a core shaft input hole (202), a core shaft output hole (203) and a core shaft hole (207) which are communicated with each other, the core shaft hole (207) is coaxially arranged in the stirring cavity (102) and the overweight cavity (103) at the center of the shaft section of the core shaft (201), the core shaft input hole (202) is radially arranged on the core shaft (201) in the stirring cavity (102) close to the position of the spacer ring (8), and the core shaft output hole (203) is radially arranged on the core shaft (201) at the root position of the overweight bed (205).

3. The high-speed water hammer composite overweight mechanism of claim 1, characterized in that: the bearing frame includes first bearing frame (4), second bearing frame (5) and third bearing frame (6), two first bearing frame (4) set up respectively at both ends bearing (3) back and support bearing (3), second bearing frame (5) set up overweight chamber (103) outside, second bearing frame (5) through first sealing washer (501) of internal diameter and external diameter department sealed respectively with clearance between dabber (201) and the stator section of thick bamboo (1), third bearing frame (6) set up stir chamber (102) outside, third bearing frame (6) through second sealing washer (601) of internal diameter and external diameter department sealed respectively with clearance between dabber (201) and the stator section of thick bamboo (1).

4. The high-speed water hammer composite overweight mechanism of claim 3, characterized in that: the middle of the third bearing seat (6) is provided with an annular groove, the input port (101) corresponds to the annular groove, and the bottom of the annular groove is provided with a low-pressure area input hole (602) facing the stirring cavity (102).

5. The high-speed water hammer composite overweight mechanism of claim 4, characterized in that: the inner side wall of the third bearing seat (6) and a spacer (7) are arranged between the spacer rings (8), and a spoiler ring for high-speed water hammer are arranged on the inner side wall of the spacer (7).

6. The high-speed water hammer composite overweight mechanism of claim 1 or 5, characterized in that: the impeller assembly (204) comprises a booster impeller unit and a stirring impeller unit which are axially connected in series.

7. The high-speed water hammer composite overweight mechanism of claim 1, characterized in that: the channel gap of the overweight reaction bed of the overweight bed (205) can be adjusted.

8. The high-speed water hammer composite overweight mechanism of claim 1, characterized in that: the stator barrel (1) and the rotor (2) are both vertically arranged, the stirring cavity (102) and the overweight cavity (103) are vertically connected in series, and the top extending end of the mandrel (201) is in transmission connection with a driving unit.

9. The high-speed water hammer composite overweight mechanism of claim 8, characterized in that: the top of the stirring cavity (102) is provided with an exhaust pipe (105) for exhausting, a material passing sieve (208) is arranged below the stirring cavity (102), and the material passing sieve (208) filters mixed liquid entering the overweight cavity (103) from the stirring cavity (102).

Images