CN116002243A - Anti-impact container - Google Patents

Abstract

The invention discloses an anti-impact container, and belongs to the technical field of hydrometallurgy. An impact resistant container comprising a base, further comprising: the storage tank is fixedly connected to the base; the buffer tank is fixedly connected to the top of the storage tank, the buffer tank comprises a tank body, a plurality of mounting pipes communicated with the inside of the tank body are fixedly connected to the tank body, and buffer columns are connected in the mounting pipes in a sliding manner; a sealing cavity is arranged between the buffer column and the mounting pipe, and a plurality of sealing cavities are mutually communicated through a first pipeline; the buffer columns are divided into two groups, and the two groups of buffer columns stretch back and forth on the mounting tube; according to the invention, the impact of the slurry on the inner wall of the tank body is eliminated by converting energy released when the high-temperature and high-pressure slurry is converted into normal-temperature and normal-pressure slurry into kinetic energy to drive the buffer column to slide, so that the damage to the container when the slurry is leached under pressure in a conversion state is reduced.

Description

Anti-impact container

Technical Field

The invention relates to the technical field of hydrometallurgy, in particular to an anti-impact container.

Background

Along with the continuous improvement of the process technology, the requirements on equipment are higher and higher to adapt to the process requirements, in hydrometallurgy, a leaching process is adopted in a large amount to realize the recovery of valuable metals, and in the leaching process, the leaching speed and the leaching rate of the metals cannot meet the process requirements due to the limitation of normal pressure leaching, so that the extraction of the valuable metals is generally realized by adopting pressure leaching in the hydrometallurgy process, after the pressure leaching is finished, slurry needs to be adjusted from a high-pressure state to a normal-pressure state, and a tank body is generally adopted for storing the slurry in a conversion state.

In the prior art, slurry is converted from a high-temperature high-pressure state to a normal-pressure normal-temperature state, a large amount of solution is gasified in the slurry, so that the volume of the slurry is rapidly expanded, the flow rate of the slurry is rapidly increased, a high-speed fluid beam is formed, strong impact is caused on the wall of a slurry container, and after the leaching process, the slurry is also provided with partial solid matters, so that the abrasion of the slurry on the wall of the container is aggravated, the container is damaged, and an anti-impact container is required to be designed in order to reduce the abrasion of the slurry on the container.

Disclosure of Invention

The invention aims to solve the problem that the container is easily damaged when the state of slurry is converted in the prior art, and provides an anti-impact container.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

an impact resistant container comprising a base, further comprising: the storage tank is fixedly connected to the base; the buffer tank is fixedly connected to the top of the storage tank, the buffer tank comprises a tank body, a plurality of mounting pipes communicated with the inside of the tank body are fixedly connected to the tank body, and buffer columns are connected in the mounting pipes in a sliding manner; a sealing cavity is arranged between the buffer column and the mounting pipe, and a plurality of sealing cavities are mutually communicated through a first pipeline; the buffer columns are divided into two groups, and the two groups of buffer columns stretch back and forth on the mounting tube; the tank body is fixedly connected with a material guide pipe, the bottom of the material guide pipe is fixedly connected with a first material discharge pipe which is obliquely arranged, and the pipe orifice of the first material discharge pipe faces the buffer column; and the control component is arranged on the material guide pipe and used for controlling the slurry to be sprayed to the corresponding buffer column.

In order to facilitate the reciprocal flexible of two sets of buffer columns of control, preferably, control assembly is including rotating the connection first installation axle in the passage, fixedly connected with turbine on the first installation axle, a plurality of first row material pipe and the junction of passage are provided with the cavity, first installation axle extends to the cavity in fixedly connected with ball valve.

In order to prevent that solid material from blocking the turbine, preferably, still include the inlet pipe, the inlet pipe includes "U" venturi tube and second pipeline, second pipeline fixed connection is in on the "U" venturi tube, first installation axle is from last first impeller of fixedly connected with and second impeller down in proper order, first impeller sets up with the second impeller both ends about the turbine, set up the filter screen in the upper segment violently intraductal of "U" venturi tube, fixedly connected with buffer block in the "U" venturi tube.

In order to facilitate solid-liquid separation, preferably, storage cavity and installation cavity have been seted up in the holding vessel, the installation cavity is located the top in storage cavity, the bottom fixedly connected with unloading pipe of jar body, the installation intracavity is rotated and is connected with the centrifuging tube, the centrifuging tube with first installation axle is fixed to link to each other, the top of centrifuging tube with unloading pipe intercommunication, the second row of material pipe of fixedly connected with in the storage cavity, the second row of material pipe with the centrifuging tube rotates to link to each other, sliding connection has the extrusion piece in the second row of material pipe, the installation intracavity rotates to be connected with the pivot, the pivot passes through sprocket assembly synchronous rotation with the centrifuging tube, fixedly connected with bent axle in the pivot, it is connected with the crank to rotate on the bent axle, the crank with the extrusion piece rotates to link to each other, the standpipe has all been seted up on the lateral wall of one section of centrifuging tube extension to the storage cavity and the second row of material pipe is located the storage cavity.

For the cooling of being convenient for, preferably, cooling water cavity and heat dissipation chamber have been seted up in the holding vessel, the heat dissipation chamber is located the top of cooling water cavity, still includes: the condenser, the pipe shaft of condenser runs through cooling water cavity and heat dissipation chamber, fixedly connected with second trachea on the upper position of the lateral wall of jar body, the second trachea links to each other with the input of condenser, the output of condenser links to each other with the storage chamber.

In order to improve cooling efficiency, preferably, a heat dissipation cavity is formed in the storage tank, a third installation shaft is rotationally connected in the heat dissipation cavity, fan blades are fixedly connected on the third installation shaft, and a first air pipe is fixedly connected to the top of the heat dissipation cavity.

In order to improve the energy utilization rate, preferably, the top fixedly connected with impeller case of holding vessel, the impeller case with the second trachea is linked together, rotate on the impeller case and be connected with the second installation axle, the second installation axle extends to impeller incasement fixedly connected with third impeller, rotate on the holding vessel and be connected with the transmission shaft, rotate in step through first bevel gear group with the second installation axle on the transmission shaft, the transmission shaft with the third installation axle passes through the synchronous rotation of second bevel gear group.

In order to improve cooling efficiency, further, fixedly connected with piston cylinder on the installation tube, fixedly connected with on the buffer column extends to the interior sealed slide bar of piston cylinder, sliding connection has with the fixed piston plate who links to each other of sealed slide bar in the piston cylinder, the input fixedly connected with of piston cylinder extends to the fourth pipeline in the storage chamber, the output of piston cylinder pass through the third pipeline with the input of condenser links to each other.

Preferably, the sealing slide bar is sleeved with a spring, and two ends of the spring are respectively propped against the buffer column and the inner wall of the mounting tube.

Compared with the prior art, the invention provides the anti-impact container which has the following beneficial effects:

1. according to the anti-impact container, energy released when high-temperature and high-pressure slurry is converted into normal-temperature and normal-pressure slurry is converted into kinetic energy to drive the buffer column to slide, so that impact of the slurry on the inner wall of the tank body is eliminated, and damage to the container when the slurry is subjected to pressure leaching in a conversion state is reduced;

2. according to the anti-impact container, the fan blades are driven to rotate by energy released when high-temperature and high-pressure slurry is converted into normal-temperature and normal-pressure slurry, air flow is generated to blow to the condenser and exchange heat with steam in the condenser to form hot air, and the hot air is blown to separated solid matters, so that the overall cooling efficiency of the slurry is improved, the utilization rate of energy is improved, and the energy loss is reduced;

3. according to the anti-impact container, energy released when high-temperature and high-pressure slurry is converted into normal-temperature and normal-pressure slurry is converted into kinetic energy to drive the piston plate to slide back and forth in the piston cylinder, steam in the storage cavity is absorbed, the steam in the storage cavity enters the condenser to be cooled and liquefied, so that the pressure in the storage cavity is reduced, more slurry can be stored, the overall cooling speed of the slurry is further improved, and the conversion efficiency of the slurry state is improved.

Drawings

FIG. 1 is a front cross-sectional view of an impact resistant container according to the present invention;

FIG. 2 is a top view of an impact resistant container according to the present invention;

FIG. 3 is a schematic diagram of a buffer tank for an anti-shock container according to the present invention;

FIG. 4 is a schematic diagram of an anti-shock container storage tank according to the present invention;

FIG. 5 is a schematic view of the structure of an anti-impact container impeller box according to the present invention;

FIG. 6 is a schematic view of a turbine of an anti-shock container according to the present invention;

FIG. 7 is a schematic diagram II of a surge tank of an anti-shock container according to the present invention;

fig. 8 is a schematic structural view of a material guiding tube of an anti-impact container according to the present invention.

In the figure: 1. a base; 2. a storage tank; 201. a storage chamber; 202. a cooling water cavity; 203. a heat dissipation cavity; 2031. a first air tube; 204. a mounting cavity; 3. a buffer tank; 301. a tank body; 302. a material guiding pipe; 303. a first discharge pipe; 3031. a cavity; 304. installing a pipe; 305. a buffer column; 306. sealing the cavity; 307. a first pipe; 308. a spring; 309. discharging pipes; 4. a feed pipe; 401. a "U" shaped tube; 402. a second pipe; 403. a filter screen; 404. a buffer block; 5. a first mounting shaft; 501. a first louver; 502. a turbine; 503. a second louver; 504. a ball valve; 6. a piston cylinder; 601. a seal slide bar; 602. a piston plate; 603. a third conduit; 604. a fourth conduit; 7. centrifuging tube; 701. a second discharge pipe; 702. extruding a block; 703. a rotating shaft; 7031. a crankshaft; 704. a crank; 705. a sprocket assembly; 706. a drain hole; 801. a second air pipe; 802. an impeller box; 8021. a second mounting shaft; 8022. a third louver; 8023. a transmission shaft; 8024. a first bevel gear set; 8025. a second bevel gear set; 8026. a third mounting shaft; 8027. a fan blade; 803. and a condenser.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Examples:

referring to fig. 1 to 8, an impact-resistant container includes a base 1, and further includes: a storage tank 2 fixedly connected to the base 1; the buffer tank 3 is fixedly connected to the top of the storage tank 2, wherein the buffer tank 3 comprises a tank body 301, a plurality of mounting pipes 304 communicated with the inside of the tank body 301 are fixedly connected to the tank body 301, and buffer columns 305 are slidably connected to the mounting pipes 304; a sealing cavity 306 is arranged between the buffer column 305 and the mounting pipe 304, and a plurality of sealing cavities 306 are communicated with each other through a first pipeline 307; the buffer columns 305 are divided into two groups, and the two groups of buffer columns 305 extend and retract back and forth on the mounting pipe 304; a material guide pipe 302 is fixedly connected to the tank 301, a first material discharge pipe 303 which is obliquely arranged is fixedly connected to the bottom of the material guide pipe 302, and the pipe orifice of the first material discharge pipe 303 faces the buffer column 305; and the control component is arranged on the material guide pipe 302 and is used for controlling the slurry to be sprayed to the corresponding buffer column 305.

The slurry after pressure leaching is sent into the material guiding pipe 302, the slurry entering the material guiding pipe 302 is sprayed out through the first material discharging pipe 303, the first material discharging pipes 303 can be arranged into four groups, two first material discharging pipes 303 which are symmetrically arranged are arranged into one group, the slurry is sprayed out from the two groups of first material discharging pipes 303 in a reciprocating manner through the control component, namely, is sprayed to the two groups of buffer columns 305 of the first material discharging pipes 303 in a reciprocating manner, the number of the buffer columns 305 is consistent with that of the first material discharging pipes 303, for convenience of description, the two groups of buffer columns 305, the corresponding first material discharging pipes 303 and the sealing cavity 306 are divided into a first group and a second group, the slurry is sprayed out to impact the corresponding first group buffer column 305, the impacted first group buffer column 305 slides into the first group installation pipe 304, at this time, the space inside the first group seal cavity 306 is reduced, fluid inside the first group seal cavity 306 is discharged into the second group seal cavity 306 through the first pipeline 307, the pressure inside the second group seal cavity 306 is increased, the second group buffer column 305 is extruded out of the second group installation pipe 304, the second group buffer column 305 slides towards the inside of the tank 301, and thus reciprocates, the energy released when the high-temperature high-pressure slurry is converted into normal-temperature normal-pressure slurry is converted into kinetic energy to drive the buffer column 305 to slide, the impact of the slurry on the inner wall of the tank 301 is eliminated, and further the loss of the container is reduced.

Referring to fig. 3, the control assembly includes a first installation shaft 5 rotatably connected in the material guiding pipe 302, a turbine 502 is fixedly connected to the first installation shaft 5, a cavity 3031 is provided at a connection position between the plurality of first material discharging pipes 303 and the material guiding pipe 302, and a ball valve 504 is fixedly connected to the first installation shaft 5 extending into the cavity 3031.

The slurry enters the material guiding pipe 302, the turbine 502 is pushed to rotate in the flowing process of the slurry, the turbine 502 drives the first installation shaft 5 to rotate, the first installation shaft 5 drives the ball valve 504 to rotate, two groups of symmetrical holes are formed in the ball valve 504, when the holes rotate to the first material discharging pipe 303 of the first group, the slurry is sprayed out of the first material discharging pipe 303 of the first group, and when the holes rotate to the first material discharging pipe 303 of the second group, the slurry is sprayed out of the first material discharging pipe 303 of the second group, so that the slurry is sprayed out of the first material discharging pipe 303 of the first group and the second material discharging pipe 303 in a reciprocating manner.

Referring to fig. 3, the utility model further includes a feeding pipe 4, the feeding pipe 4 includes a "U" pipe 401 and a second pipe 402, the second pipe 402 is fixedly connected on the "U" pipe 401, a first installation shaft 5 is fixedly connected with a first blade 501 and a second blade 503 in sequence from top to bottom, the first blade 501 and the second blade 503 are disposed at the upper and lower ends of the turbine 502, a filter screen 403 is disposed in the upper transverse pipe of the "U" pipe 401, and a buffer block 404 is fixedly connected in the "U" pipe 401.

The slurry after pressure leaching is sent into a feeding pipe 4, the slurry is shunted through a U-shaped pipe 401 in the process of entering, part of the slurry is filtered out of solid objects through a filter screen 403, then enters a guide pipe 302 and is sprayed to a first blade 501 to push the first blade 501 to rotate, further power is provided for the rotation of a first mounting shaft 5, the rest of solid objects are mixed with the rest of liquid to be sprayed to a second blade 503 through a transverse pipe at the bottom of the U-shaped pipe 401, the first mounting shaft 5 is further driven to rotate through the second blade 503, the self energy of the slurry after pressure leaching is fully utilized, the slurry is shunted through the U-shaped pipe 401 and is filtered through the filter screen 403, and thus the turbine 502 is prevented from being blocked by solid substances, and the first mounting shaft 5 can keep rotating normally.

Referring to fig. 3 and 4, a storage cavity 201 and a mounting cavity 204 are formed in the storage tank 2, the mounting cavity 204 is located above the storage cavity 201, a blanking pipe 309 is fixedly connected to the bottom of the tank 301, a centrifuge tube 7 is rotatably connected to the mounting cavity 204, the centrifuge tube 7 is fixedly connected to the first mounting shaft 5, the top of the centrifuge tube 7 is communicated with the blanking pipe 309, a second discharging pipe 701 is fixedly connected to the storage cavity 201, the second discharging pipe 701 is rotatably connected to the centrifuge tube 7, an extrusion block 702 is slidably connected to the second discharging pipe 701, a rotating shaft 703 is rotatably connected to the mounting cavity 204, the rotating shaft 703 and the centrifuge tube 7 are synchronously rotated through a sprocket assembly 705, a crankshaft 7031 is fixedly connected to the rotating shaft 703, a crank 704 is rotatably connected to the rotating shaft 7031, and a drain hole 706 is formed in a side wall of a section of the centrifuge tube 7 extending to the storage cavity 201 and a stand pipe of the second discharging pipe 701 located in the storage cavity 201.

The buffered slurry falls to the bottom of the tank 301 from the buffer column 305 and flows into the centrifuge tube 7 through the blanking tube 309, the first mounting shaft 5 drives the centrifuge tube 7 to rotate, the liquid in the slurry is discharged out of the centrifuge tube 7 through the drain hole 706 on the centrifuge tube 7, the solid matters fall into the second discharge tube 701, meanwhile, the centrifuge tube 7 drives the rotating shaft 703 to rotate through the sprocket assembly 705, the rotating shaft 703 drives the crankshaft 7031 to rotate, the crankshaft 7031 drives the extrusion block 702 to slide reciprocally through the crank 704, the extrusion block 702 slides reciprocally to push the solid matters falling into the second discharge tube 701 reciprocally, and as the materials increase, the solid matters gradually flow out of the tank 301 along the second discharge tube 701, and in the solid matters discharging process, the solid matters are pushed by extrusion, the residual liquid can be extruded in the moving process, the extruded liquid is discharged through the drain hole 706, and the solid matters and the liquid is directly separated from the liquid.

In addition, the second material discharging pipe 701 can be set as a straight pipe with a certain angle tilted upwards, the pipe wall is still provided with a water discharging hole 706, and then a group of electric augers are installed on the material discharging pipe, and the electric augers are used for discharging solid objects, which is not described herein.

Referring to fig. 1-4, a cooling water cavity 202 and a heat dissipation cavity 203 are formed in the storage tank 2, the heat dissipation cavity 203 is located above the cooling water cavity 202, and further includes: the condenser 803, the pipe shaft of condenser 803 runs through cooling water cavity 202 and heat dissipation chamber 203, and the upper position of the lateral wall of jar body 301 is fixed connection with second trachea 801, and second trachea 801 links to each other with the input of condenser 803, and the output of condenser 803 links to each other with storage chamber 201.

When the leached slurry is initially introduced into the tank 301, the temperature and the pressure of the leached slurry are relatively high, the temperature and the pressure of the leached slurry are initially reduced in the tank 301 to form high-temperature gas, and the high-temperature gas is kept at a relatively high pressure, the gas pressure in the tank 301 is larger than the gas pressure in the condenser 803, so that the high-temperature gas in the tank 301 enters the second gas pipe 801 and then enters the condenser 803 to exchange heat, and the high-temperature gas exchanges heat with cooling water in the cooling water cavity 202 in the condenser 803 to be liquefied again into liquid and then flows into the storage cavity 201.

Referring to fig. 1-3, a heat dissipation chamber 203 is provided in a storage tank 2, a third mounting shaft 8026 is rotationally connected in the heat dissipation chamber 203, a fan blade 8027 is fixedly connected on the third mounting shaft 8026, a first air pipe 2031 is fixedly connected at the top of the heat dissipation chamber 203, an impeller box 802 is fixedly connected at the top of the storage tank 2, the impeller box 802 is communicated with a second air pipe 801, a second mounting shaft 8021 is rotationally connected on the impeller box 802, the second mounting shaft 8021 extends into the impeller box 802 and is fixedly connected with a third blade 8022, a transmission shaft 8023 is rotationally connected on the storage tank 2, the transmission shaft 8023 and the second mounting shaft 8021 synchronously rotate through a first bevel gear set 8024, and the transmission shaft 8023 and the third mounting shaft 8026 synchronously rotate through a second bevel gear set 8025.

The high-temperature high-pressure gas passes through the impeller box 802 before entering the condenser 803, pushes the third impeller 8022 to rotate, further drives the second mounting shaft 8021 to rotate, drives the transmission shaft 8023 to rotate through the first bevel gear set 8024, drives the third mounting shaft 8026 to rotate through the second bevel gear set 8025 by the transmission shaft 8023, further drives the fan blades 8027 to rotate, blows the condenser 803 to a pipeline positioned in the heat dissipation cavity 203, forms hot air to be discharged into the first air pipe 2031, the air outlet of the first air pipe 2031 can be communicated with an air cylinder for drying solid objects, the drying speed of the solid objects is improved while the energy utilization rate is improved by utilizing the hot air, the cooling efficiency of the gas is improved, or the hot air is led into slurry to be leached by pressure to preheat the slurry, and the pressure leaching efficiency is improved.

Referring to fig. 1-4, a piston cylinder 6 is fixedly connected to a mounting tube 304, a sealing slide bar 601 extending into the piston cylinder 6 is fixedly connected to a buffer post 305, a piston plate 602 fixedly connected to the sealing slide bar 601 is slidably connected to the piston cylinder 6, a fourth pipeline 604 extending into a storage cavity 201 is fixedly connected to an input end of the piston cylinder 6, an output end of the piston cylinder 6 is connected to an input end of a condenser 803 through a third pipeline 603, a spring 308 is sleeved on the sealing slide bar 601, and two ends of the spring 308 are respectively abutted against the buffer post 305 and an inner wall of the mounting tube 304.

When the buffer column 305 slides reciprocally, the buffer column 305 slides by driving the seal slide bar 601, the seal slide bar 601 drives the piston plate 602 to slide reciprocally in the piston cylinder 6, the output end and the input end of the piston cylinder 6 are both provided with one-way valves, when the piston plate 602 slides obliquely upwards, the piston cylinder 6 absorbs steam which drifts in the storage cavity 201 through the fourth pipeline 604, and when the piston plate 602 slides obliquely downwards, the steam which is absorbed into the piston cylinder 6 is pressed into the condenser 803 through the third pipeline 603, so that the steam is cooled and liquefied in the condenser 803, the pressure in the storage cavity 201 is reduced, the integral cooling speed of the slurry is accelerated while the storage capacity is improved, and the static efficiency of the slurry converted from high temperature and high pressure dynamic to normal temperature and normal pressure is improved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (9)

1. An anti-impact container comprising a base (1), characterized in that it further comprises:

a storage tank (2) fixedly connected to the base (1);

a buffer tank (3) fixedly connected to the top of the storage tank (2),

the buffer tank (3) comprises a tank body (301), wherein a plurality of mounting pipes (304) communicated with the inside of the tank body (301) are fixedly connected to the tank body (301), and buffer columns (305) are slidably connected to the mounting pipes (304);

a sealing cavity (306) is arranged between the buffer column (305) and the mounting pipe (304), and a plurality of sealing cavities (306) are mutually communicated through a first pipeline (307);

the buffer columns (305) are divided into two groups, and the two groups of buffer columns (305) are in reciprocating expansion and contraction on the mounting pipe (304);

a material guide pipe (302) is fixedly connected to the tank body (301), a first material discharge pipe (303) which is obliquely arranged is fixedly connected to the bottom of the material guide pipe (302), and a pipe orifice of the first material discharge pipe (303) faces the buffer column (305);

and the control assembly is arranged on the material guide pipe (302) and is used for controlling the slurry to be sprayed to the corresponding buffer column (305).

2. The anti-impact container according to claim 1, wherein the control assembly comprises a first mounting shaft (5) rotatably connected in the material guiding pipe (302), a turbine (502) is fixedly connected to the first mounting shaft (5), a cavity (3031) is formed at the joint of a plurality of first material discharging pipes (303) and the material guiding pipe (302), and a ball valve (504) is fixedly connected to the first mounting shaft (5) extending into the cavity (3031).

3. The anti-impact container according to claim 2, further comprising a feeding pipe (4), wherein the feeding pipe (4) comprises a U-shaped pipe (401) and a second pipeline (402), the second pipeline (402) is fixedly connected to the U-shaped pipe (401), a first blade (501) and a second blade (503) are sequentially and fixedly connected to the first mounting shaft (5) from top to bottom, the first blade (501) and the second blade (503) are arranged at the upper end and the lower end of the turbine (502), a filter screen (403) is arranged in an upper transverse pipe of the U-shaped pipe (401), and a buffer block (404) is fixedly connected to the U-shaped pipe (401).

4. The anti-impact container according to claim 3, wherein a storage cavity (201) and a mounting cavity (204) are formed in the storage tank (2), the mounting cavity (204) is located above the storage cavity (201), a blanking pipe (309) is fixedly connected to the bottom of the tank body (301), a centrifuge tube (7) is rotationally connected to the mounting cavity (204), the centrifuge tube (7) is fixedly connected to the first mounting shaft (5), the top of the centrifuge tube (7) is communicated with the blanking pipe (309), a second discharging pipe (701) is fixedly connected to the storage cavity (201), the second discharging pipe (701) is rotationally connected to the centrifuge tube (7), a pressing block (702) is slidingly connected to the second discharging pipe (701), a rotating shaft (703) is rotationally connected to the mounting cavity (204), the rotating shaft (703) is rotationally synchronous with the centrifuge tube (7) through a sprocket assembly (705), the rotating shaft (703) is fixedly connected to the first mounting shaft (5), the top of the centrifuge tube (7) is communicated with the blanking pipe (309), a second discharging pipe (701) is rotationally connected to the crankshaft (704), and the crank (704) is rotationally connected to the crank (704), drainage holes (706) are formed in the side wall of a section of the centrifuge tube (7) extending to the storage cavity (201) and in the vertical tube of the second discharge tube (701) located in the storage cavity (201).

5. The anti-impact container according to claim 4, wherein the storage tank (2) is provided with a cooling water cavity (202) and a heat dissipation cavity (203), and the heat dissipation cavity (203) is located above the cooling water cavity (202), and further comprises:

the condenser (803), the pipe shaft of condenser (803) runs through cooling water cavity (202) and heat dissipation chamber (203), fixedly connected with second trachea (801) on the position that the lateral wall of jar body (301) is on the upper side, second trachea (801) link to each other with the input of condenser (803), the output of condenser (803) links to each other with storage chamber (201).

6. The anti-impact container according to claim 5, wherein a heat dissipation cavity (203) is formed in the storage tank (2), a third installation shaft (8026) is rotatably connected in the heat dissipation cavity (203), fan blades (8027) are fixedly connected on the third installation shaft (8026), and a first air pipe (2031) is fixedly connected at the top of the heat dissipation cavity (203).

7. The anti-impact container according to claim 6, wherein an impeller box (802) is fixedly connected to the top of the storage tank (2), the impeller box (802) is communicated with the second air pipe (801), a second mounting shaft (8021) is rotatably connected to the impeller box (802), a third blade (8022) is fixedly connected to the second mounting shaft (8021) in the impeller box (802), a transmission shaft (8023) is rotatably connected to the storage tank (2), the transmission shaft (8023) and the second mounting shaft (8021) are synchronously rotated through a first bevel gear set (8024), and the transmission shaft (8023) and the third mounting shaft (8026) are synchronously rotated through a second bevel gear set (8025).

8. The anti-impact container according to claim 5, wherein the mounting tube (304) is fixedly connected with a piston cylinder (6), the buffer column (305) is fixedly connected with a sealing slide bar (601) extending into the piston cylinder (6), a piston plate (602) fixedly connected with the sealing slide bar (601) is slidably connected in the piston cylinder (6), the input end of the piston cylinder (6) is fixedly connected with a fourth pipeline (604) extending into the storage cavity (201), and the output end of the piston cylinder (6) is connected with the input end of the condenser (803) through a third pipeline (603).

9. The anti-impact container according to claim 8, wherein the sealing slide bar (601) is sleeved with a spring (308), and two ends of the spring (308) are respectively abutted against the buffer column (305) and the inner wall of the mounting tube (304).

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