CN117225544B - Rinsing equipment with crushing mechanism for silicon micropowder production and rinsing method thereof - Google Patents

Abstract

The invention belongs to the technical field of silica powder rinsing, and discloses rinsing equipment with a crushing mechanism for silica powder production and a rinsing method thereof. The invention solves the problem that the accumulated caking is not thoroughly rinsed in the cleaning process of the silica powder.

Description

Rinsing equipment with crushing mechanism for silicon micropowder production and rinsing method thereof

Technical Field

The invention relates to the technical field of silica micropowder rinsing, in particular to rinsing equipment with a crushing mechanism for silica micropowder production and a rinsing method thereof.

Background

The silicon micropowder refers to quartz powder generally, and is prepared from pure quartz (natural quartz or fused quartz) by crushing, sorting, cleaning, acid treatment, high-temperature melting, medium crushing, fine grinding, grading, iron removal and other steps.

The rinsing equipment with the crushing mechanism for producing the silicon micro powder and the rinsing method thereof have the publication number CN113751117B, and adopt a mode of enabling a convex shaft on a rotating disc to be matched with a moving rod with a straight hole based on the rotation of the rotating disc, so that the moving rod carries a moving box to reciprocate in the rinsing box through a connecting rod; the crushing roller is fixed in position, so that the crushing roller crushes quartz on the screen plate; the lower part of the movable box is immersed into the liquid level, and the silicon micro powder generated by crushing is quickly rinsed in the reciprocating movement process.

However, when the device is used for rinsing the silica fume, the crushed silica fume is easy to accumulate, so that the rinsing is not thorough.

Disclosure of Invention

The invention aims to provide rinsing equipment with a crushing mechanism for producing silicon micropowder and a rinsing method thereof, which solve the problem that the rinsing of accumulated caking is not thorough in the cleaning process of the silicon micropowder.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a take reducing mechanism's rinsing equipment for silica powder production, includes first shell, control panel is installed to first shell outer wall, and the discharge gate is installed to first shell lower terminal surface, installs the second shell on the inside diapire of first shell, and the second shell upper end runs through first shell, the storage silo is installed to first shell up end symmetry, the pan feeding mouth has been seted up to second shell outer wall symmetry, and pan feeding mouth and storage silo intercommunication each other, first backup pad and baffle are installed in proper order from last to lower to the second shell inner wall, elevating system is installed to first backup pad top, rolling mechanism is installed to the baffle below.

Preferably, the lifting mechanism comprises a servo motor, the upper end face of the servo motor is fixedly arranged on the second shell, a second belt pulley is fixedly arranged on an output shaft of the servo motor, a first belt and a second belt are sequentially sleeved outside the second belt pulley from top to bottom, a first belt pulley is sleeved inside one side of the first belt, which is far away from the servo motor, and a third belt pulley is sleeved inside one side of the second belt, which is far away from the servo motor.

Preferably, the first belt pulley and the third belt pulley are rotatably arranged on the upper end face of the first supporting plate, first round rods are sleeved inside the first belt pulley and the third belt pulley, limiting rods are symmetrically arranged on the outer walls of the first round rods, first screw rods are fixedly arranged on the lower end faces of the first round rods, second round rods are sleeved on the lower end faces of the first screw rods, the lower ends of the second round rods are fixedly arranged on the bottom wall of the first shell, fixing frames are fixedly arranged on the upper end faces of the second round rods, thread blocks are sleeved on the outer walls of the first screw rods, filter plates are arranged on one sides of the thread blocks facing the servo motors, and baffle plates are symmetrically arranged on the lower end faces of the filter plates.

Preferably, the rolling mechanism comprises a shaking assembly and an adjusting assembly, the shaking assembly comprises two cams, a fourth round bar is abutted to the lower end face of each cam, a first sliding bar is fixedly arranged on one side of each fourth round bar, the upper end and the lower end of each first sliding bar penetrate through a second shell and a first supporting plate respectively, a first rack is fixedly arranged on one side of each first sliding bar, which is far away from each fourth round bar, a first gear is meshed on one side of each first sliding bar, a fixed block is rotationally symmetrically arranged on the outer wall of each first gear, the lower end face of each fixed block is fixedly arranged on the first supporting plate, a second rack is meshed on one side of each first gear, which is far away from each first gear, a second sliding plate is arranged on one side of each second rack, the upper end of each second sliding plate penetrates through the second shell, and the lower end of each second sliding plate penetrates through the first supporting plate.

Preferably, the adjusting component comprises an inner gear and a second gear, the inner gear is rotationally connected with the first supporting plate, a third round rod is installed on the lower end face of the second gear, a supporting block is fixedly installed at the lower end of the third round rod, the outer wall of the supporting block is rotationally symmetrically provided with a crushing roller, springs are fixedly symmetrically installed on the upper end face of the second supporting plate, a second screw rod is sleeved inside the springs, the lower end of the second screw rod penetrates through the second supporting plate and is fixedly installed on the partition plate, a screw cap is arranged on the screw thread sleeve on the outer wall of the second screw rod, and the lower end face of the screw cap is abutted to the springs.

Preferably, the first belt pulley and the third belt pulley are the same in size, and the second belt pulley is twice as large as the first belt pulley.

Preferably, the rinsing method for producing the silicon micro powder with the crushing mechanism comprises the following steps of:

The first step: firstly, injecting a proper amount of pure water into the second shell, then, operating the control panel to set related parameters, putting the silicon micro powder into the storage bin, driving the filter plate to ascend or descend by the lifting mechanism, rinsing the silicon micro powder, and intermittently enabling the silicon micro powder in the storage bin to enter the second shell;

and a second step of: when the filter plate rises or descends, the shaking component shakes the filter plate to prevent the silicon micro powder from agglomerating, and when the filter plate rises to the highest, the crushing roller can crush the residual silicon micro powder on the filter plate, and the crushing degree is regulated by the regulating component.

Compared with the prior art, the invention has the following beneficial effects:

1. According to the invention, by arranging the lifting mechanism, when the first screw rod rotates, the filter plate is driven to ascend or descend through the threaded block, the filter plate drives the baffle plate to move, when the filter plate ascends, the baffle plate can close the feeding port, and when the filter plate descends, the feeding port is opened to finish intermittent discharging, so that accumulation is prevented;

2. According to the invention, the shaking component is arranged, the first screw rod drives the cam to rotate, when the cam bulge part presses the fourth round rod, the cam drives the first round rod to move upwards, the first round rod drives the first screw rod to ascend, the first screw rod rotates in the second round rod and simultaneously moves upwards, the first screw rod drives the filter plate to ascend through the threaded block, when the cam bulge part does not press the fourth round rod, the silicon micro powder and the filter plate naturally fall due to self gravity, and the second belt pulley is twice as large as the first belt pulley and the third belt pulley, so that the first belt pulley and the third belt pulley rotate fast, the cam rotates fast, the filter plate shakes up and down frequently in pure water, and the silicon micro powder is prevented from accumulating and agglomerating.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a schematic illustration of the present invention with a first housing removed;

FIG. 4 is a schematic illustration of FIG. 3 with a second housing removed;

FIG. 5 is a schematic view of a lifting mechanism according to the present invention;

FIG. 6 is an enlarged schematic view of FIG. 5A;

FIG. 7 is a schematic view of a laminating mechanism according to the present invention;

Fig. 8 is a schematic view of fig. 7 at another view angle.

In the figure: 1. a first housing; 2. a control panel; 3. support legs; 4. a discharge port; 5. a second housing; 6. a storage bin; 7. a feed inlet; 8. a partition plate; 9. a first support plate; 100. a lifting mechanism; 200. a rolling mechanism; 101. a servo motor; 102. a first pulley; 103. a first belt; 104. a first round bar; 105. a first screw rod; 106. a second pulley; 107. a third pulley; 108. a second belt; 109. a limit rod; 110. a filter plate; 111. a screw block; 112. a baffle; 113. a fixing frame; 114. a second round bar; 201. a cam; 202. a first slide bar; 203. a first rack; 204. a first gear; 205. a second slide plate; 206. a second rack; 207. a second gear; 208. a third round bar; 209. a second screw rod; 210. a second support plate; 211. an internal gear; 212. a fourth round bar; 213. a through hole; 214. a screw cap; 215. a spring; 216. a support block; 217. a pulverizing roller; 218. and a fixed block.

Detailed Description

Referring to fig. 1 to 8, the present invention provides a technical solution: the utility model provides a take rinsing equipment for silica flour production of reducing mechanism, includes first shell 1, control panel 2 is installed to first shell 1 outer wall, and discharge gate 4 is installed to first shell 1 lower terminal surface, installs second shell 5 on the inside diapire of first shell 1, and second shell 5 upper end runs through first shell 1, storage silo 6 is installed to first shell 1 up end symmetry, feed inlet 7 has been seted up to second shell 5 outer wall symmetry, and feed inlet 7 communicates with storage silo 6 each other, first backup pad 9 and baffle 8 are installed in proper order from top to bottom to second shell 5 inner wall, elevating system 100 is installed to first backup pad 9 top, rolling mechanism 200 is installed to baffle 8 below, a plurality of supporting leg 3 is installed to first shell 1 lower terminal surface, discharge gate 4 internally mounted has the solenoid valve;

The control panel 2 sets relevant parameters;

Further, as shown in fig. 5 and 6, the lifting mechanism 100 includes a servo motor 101, the upper end surface of the servo motor 101 is fixedly mounted on the second housing 5, the output shaft of the servo motor 101 is fixedly mounted with a second belt pulley 106, a first belt 103 and a second belt 108 are sequentially sleeved outside the second belt pulley 106 from top to bottom, a first belt pulley 102 is sleeved inside one side of the first belt 103 away from the servo motor 101, a third belt pulley 107 is sleeved inside one side of the second belt 108 away from the servo motor 101, the first belt pulley 102 and the third belt pulley 107 are rotatably mounted on the upper end surface of the first support plate 9, first round rods 104 are sleeved inside the first belt pulley 102 and the third belt pulley 107, the outer wall of the first round rods 104 is symmetrically provided with a limiting rod 109, the lower end surface of the first round rods 104 is fixedly provided with a first screw rod 105, the lower end of the first screw rod 105 is sleeved with a second round rod 114, the lower end of the second round rod 114 is fixedly mounted on the bottom wall of the first housing 1, the upper end surface of the second belt pulley 114 is fixedly provided with a third belt pulley 107, the second round rod 105 is fixedly provided with a second round rod 114, the second round rod 105 is fixedly provided with a small pulley block 113 facing the first round rod 102 and the second round rod 102 is provided with a small thread 110, and the second round rod 110 is provided with a large thread 110;

The servo motor 101 drives the second belt pulley 106 to rotate, the second belt pulley 106 drives the first belt 103 and the second belt 108 to rotate, the first belt 103 and the second belt 108 drive the first belt pulley 102 and the third belt pulley 107 to rotate respectively, the first belt pulley 102 and the third belt pulley 107 drive the first round rod 104 to rotate respectively, the first round rod 104 drives the first screw rod 105 to rotate, and as the threaded block 111 is in threaded connection with the first screw rod 105, the threaded block 111 drives the filter plate 110 to ascend or descend, when the filter plate 110 ascends or descends, the baffle 112 is driven to ascend or descend, the baffle 112 ascends to close the feed inlet 7, the silicon micro powder in the storage bin 6 is prevented from falling, the baffle 112 descends, the feed inlet 7 is opened, the silicon micro powder in the storage bin 6 is prevented from falling, intermittent blanking is realized, and accumulation is prevented;

Further, as shown in fig. 7 and 8, the rolling mechanism 200 includes a shaking assembly and an adjusting assembly, the shaking assembly includes two cams 201, the lower end surfaces of the two cams 201 are abutted to a fourth round bar 212, a first sliding bar 202 is fixedly installed on one side of the fourth round bar 212 far away from the cams 201, the upper end and the lower end of the first sliding bar 202 respectively penetrate through the second housing 5 and the first supporting plate 9, a first rack 203 is fixedly installed on one side of the first sliding bar 202 far away from the fourth round bar 212, a first gear 204 is meshed on one side of the first rack 203 far away from the first sliding bar 202, a fixing block 218 is installed on the outer wall of the first gear 204 in a rotationally symmetrical manner, the lower end surface of the fixing block 218 is fixedly installed on the first supporting plate 9, a second rack 206 is meshed on one side of the first gear 204 far away from the first rack 203, a second sliding plate 205 is installed on one side of the second rack 206 far away from the first gear 204, the upper end of the second sliding plate 205 penetrates through the second housing 5, the lower end of the second sliding plate 205 penetrates through the first supporting plate 9 and is fixedly provided with a second supporting plate 210, the adjusting component comprises an inner gear 211 and a second gear 207, the inner gear 211 is rotationally connected with the first supporting plate 9, a third round rod 208 is installed on the lower end face of the second gear 207, a supporting block 216 is fixedly installed at the lower end of the third round rod 208 in sequence penetrating through the second supporting plate 210 and the partition plate 8, crushing rollers 217 are rotationally symmetrically installed on the outer wall of the supporting block 216, springs 215 are fixedly and symmetrically installed on the upper end face of the second supporting plate 210, a second screw rod 209 is sleeved inside the springs 215, the lower end of the second screw rod 209 penetrates through the second supporting plate 210 and is fixedly installed on the partition plate 8, a screw cap 214 is sleeved on the outer wall of the second screw rod 209, the lower end face of the screw cap 214 is abutted on the springs 215, the lower end of the second belt pulley 106 penetrates through the first supporting plate 9 and is fixedly connected with the inner gear 211, and through holes 213 are symmetrically formed in the lower end face of the first supporting plate 9;

When the first screw rod 105 rotates, the first screw rod 105 drives the cam 201 to rotate, when the protruding part of the cam 201 presses the fourth round rod 212, the cam 201 drives the first round rod 104 to move upwards, the first round rod 104 drives the first screw rod 105 to ascend, the first screw rod 105 rotates in the second round rod 114 and simultaneously moves upwards, the first screw rod 105 drives the filter plate 110 to ascend through the threaded block 111, when the protruding part of the cam 201 does not press the fourth round rod 212, the filter plate 110 naturally falls due to the gravity of the silicon micropowder and the self, and because the second belt pulley 106 is twice as large as the first belt pulley 102 and the third belt pulley 107, the first belt pulley 102 and the third belt pulley 107 rotate fast, the cam 201 rotates fast, the filter plate 110 shakes up and down frequently in pure water, the silicon micropowder is prevented from piling up, and the micro silicon micropowder is accelerated to fall down;

When the filter plate 110 rises to a certain height, the crushing roller 217 starts to be extruded, the crushing roller 217 upwards extrudes the third round rod 208 through the supporting block 216, the third round rod 208 drives the second supporting plate 210 and the second gear 207 to rise, the second supporting plate 210 extrudes the spring 215, at the moment, the elasticity of the spring 215 can be adjusted through the rotating nut 214, so that the crushing work of the silicon micro powder with different degrees is realized, along with the rising of the second gear 207, the threaded part of the first screw rod 105 reaches the top end, the second gear 207 drives the third round rod 208 to rotate, the third round rod 208 drives the crushing roller 217 to rotate through the supporting block 216, the silicon micro powder on the filter plate 110 is crushed again, and qualified silicon micro powder falls into pure water from the filter plate 110;

When the second support plate 210 ascends, the second slide plate 205 is driven to ascend, the second slide plate 205 drives the second rack 206 to ascend, the first gear 204 rotates due to the mutual engagement of the first gear 204 and the second rack 206, the first rack 203 moves downwards due to the mutual engagement of the first rack 203 and the first gear 204, the first rack 203 drives the first slide bar 202 to move downwards, the first slide bar 202 drives the fourth round bar 212 to move downwards, and at the moment, the fourth round bar 212 is not abutted with the cam 201, so that the filter plate 110 does not shake, and the non-uniformity of crushing of the crushing roller 217 is prevented;

when the second supporting plate 210 descends, the second sliding plate 205 is driven to descend, the second sliding plate 205 drives the second rack 206 to descend, the first gear 204 reversely rotates due to the mutual engagement of the first gear 204 and the second rack 206, the first rack 203 moves upwards due to the mutual engagement of the first rack 203 and the first gear 204, the first rack 203 drives the first sliding rod 202 to move upwards, the first sliding rod 202 drives the fourth round rod 212 to move upwards, and at the moment, the fourth round rod 212 is abutted with the cam 201;

In this embodiment, the rinsing method for producing the silica powder with the pulverizing mechanism includes the following steps:

The first step: setting related parameters through a control panel 2, adding a proper amount of pure water through a feed inlet 7 through a storage bin 6, enabling a servo motor 101 to rotate through the control panel 2, enabling the servo motor 101 to drive a second belt pulley 106 to rotate, enabling the second belt pulley 106 to drive an inner gear 211, a first belt 103 and a second belt 108 to rotate, enabling the first belt pulley 102 and the second belt 108 to drive a first belt pulley 102 and a third belt pulley 107 to rotate respectively, enabling the first belt pulley 102 and the third belt pulley 107 to drive a first round rod 104 to rotate, enabling the first round rod 104 to drive a first screw rod 105 to rotate, enabling a thread block 111 to be in threaded connection with the first screw rod 105, enabling a filter plate 110 to be driven to ascend by the thread block 111, then placing primarily crushed silicon micro powder into the storage bin 6, enabling the silicon micro powder to enter the upper portion of the filter plate 110 through the feed inlet 7, immersing the filter plate 110 into the pure water for rinsing, and enabling particles to fall down through the filter plate 110;

When the filter plate 110 ascends, the baffle plate 112 is driven to ascend, the baffle plate 112 can enable the feed inlet 7 to be closed, the silicon micro powder in the storage bin 6 is prevented from falling, when the filter plate 110 descends, the baffle plate 112 is driven to descend, the baffle plate 112 can enable the feed inlet 7 to be opened, the silicon micro powder in the storage bin 6 is enabled to fall, intermittent blanking is achieved, and accumulation is prevented;

And a second step of: when the first screw rod 105 rotates, the first screw rod 105 drives the cam 201 to rotate, when the protruding part of the cam 201 presses the fourth round rod 212, the cam 201 drives the first round rod 104 to move upwards, the first round rod 104 drives the first screw rod 105 to ascend, the first screw rod 105 rotates in the second round rod 114 and simultaneously moves upwards, the first screw rod 105 drives the filter plate 110 to ascend through the threaded block 111, when the protruding part of the cam 201 does not press the fourth round rod 212, the filter plate 110 naturally falls due to the gravity of the silicon micro powder and the self, and because the second belt pulley 106 is twice as large as the first belt pulley 102 and the third belt pulley 107, the first belt pulley 102 and the third belt pulley 107 rotate fast, the cam 201 rotates fast, the filter plate 110 shakes up and down frequently in pure water, and the silicon micro powder is prevented from accumulating and agglomerating;

When the filter plate 110 rises to a certain height, the crushing roller 217 starts to be extruded, the crushing roller 217 upwards extrudes the third round rod 208 through the supporting block 216, the third round rod 208 drives the second supporting plate 210 and the second gear 207 to rise, the second supporting plate 210 extrudes the spring 215, at the moment, the elasticity of the spring 215 can be adjusted through the rotating nut 214, so that the crushing work of the silicon micro powder with different degrees is realized, along with the rising of the second gear 207, the threaded part of the first screw rod 105 reaches the top end, the second gear 207 drives the third round rod 208 to rotate, the third round rod 208 drives the crushing roller 217 to rotate through the supporting block 216, the silicon micro powder on the filter plate 110 is crushed again, and qualified silicon micro powder falls into pure water from the filter plate 110;

When the second support plate 210 ascends, the second slide plate 205 is driven to ascend, the second slide plate 205 drives the second rack 206 to ascend, the first gear 204 rotates due to the mutual engagement of the first gear 204 and the second rack 206, the first rack 203 moves downwards due to the mutual engagement of the first rack 203 and the first gear 204, the first rack 203 drives the first slide bar 202 to move downwards, the first slide bar 202 drives the fourth round bar 212 to move downwards, and at the moment, the fourth round bar 212 is not abutted with the cam 201, so that the filter plate 110 does not shake, and the non-uniformity of crushing of the crushing roller 217 is prevented;

When the servo motor 101 rotates for a certain time, the first screw rod 105 starts to reversely rotate, at this time, the filter plate 110 moves downwards, the crushing roller 217 is not extruded, the spring 215 rebounds to drive the second support plate 210 and the crushing roller 217 to return to the initial position, the second gear 207 is not meshed with the inner gear 211, when the crushing roller 217 does not work, the service life is effectively prolonged, meanwhile, when the second support plate 210 descends, the second slide plate 205 is driven to descend, the second slide plate 205 drives the second rack 206, the second rack 206 enables the first gear 204 to reversely rotate, the first gear 204 drives the first rack 203 to move upwards, the first rack 203 drives the first slide rod 202 to move upwards, the first slide rod 202 drives the first round rod 104 to ascend to abut against the cam 201, at this time, the filter plate 110 descends and simultaneously shakes again, the silicon micropowder is rinsed again, and the steps are repeated for a plurality of times, and after all the steps are finished, the silicon micropowder is discharged from the discharge port 4.

Claims (5)

1. Rinsing equipment is used in silica powder production of taking reducing mechanism, including first shell (1), its characterized in that: the automatic feeding device is characterized in that a control panel (2) is arranged on the outer wall of the first shell (1), a discharge hole (4) is arranged on the lower end face of the first shell (1), a second shell (5) is arranged on the inner bottom wall of the first shell (1), the upper end of the second shell (5) penetrates through the first shell (1), a storage bin (6) is symmetrically arranged on the upper end face of the first shell (1), a feed inlet (7) is symmetrically arranged on the outer wall of the second shell (5), the feed inlet (7) is communicated with the storage bin (6), a first supporting plate (9) and a partition plate (8) are sequentially arranged on the inner wall of the second shell (5) from top to bottom, a lifting mechanism (100) is arranged above the first supporting plate (9), and a rolling mechanism (200) is arranged below the partition plate (8);

The novel filter plate comprises a first belt pulley (102) and a third belt pulley (107), wherein a first round rod (104) is sleeved inside the first belt pulley and the third belt pulley, a limit rod (109) is symmetrically arranged on the outer wall of the first round rod (104), a first screw rod (105) is fixedly arranged on the lower end face of the first round rod (104), a second round rod (114) is sleeved on the lower end of the first screw rod (105), the lower end of the second round rod (114) is fixedly arranged on the bottom wall of a first shell (1), a fixing frame (113) is fixedly arranged on the upper end face of the second round rod (114), a thread block (111) is sleeved on the outer wall of the first screw rod (105), a filter plate (110) is arranged on one side of the thread block (111) facing the servo motor (101), and a baffle (112) is symmetrically arranged on the lower end face of the filter plate (110);

The rolling mechanism (200) comprises a shaking assembly and an adjusting assembly, the shaking assembly comprises two cams (201), the lower end faces of the cams (201) are abutted to fourth round rods (212), one side, far away from the cams (201), of each fourth round rod (212) is fixedly provided with a first sliding rod (202), the upper end and the lower end of each first sliding rod (202) penetrate through a second shell (5) and a first supporting plate (9) respectively, one side, far away from the fourth round rods (212), of each first sliding rod (202) is fixedly provided with a first rack (203), one side, far away from the first sliding rod (202), of each first rack (203) is meshed with a first gear (204), the outer wall of each first gear (204) is rotationally symmetrically provided with a fixed block (218), the lower end faces of the fixed blocks (218) are fixedly provided with a first supporting plate (9), one side, far away from the first racks (203), of each second racks (206) are meshed with second racks (206), one sides, far away from the first racks (204), are respectively, second racks (205) are installed on one sides, far away from the first racks (205), one sides, and the upper ends of the second racks (205) are fixedly provided with second supporting plates (205), and the second supporting plates (205) are penetrated through the second shells.

The adjusting assembly comprises an inner gear (211) and a second gear (207), the inner gear (211) is rotationally connected with a first supporting plate (9), a third round rod (208) is installed on the lower end face of the second gear (207), a supporting block (216) is fixedly installed at the lower end of the third round rod (208) in sequence penetrating through a second supporting plate (210) and a partition plate (8), a crushing roller (217) is installed on the outer wall of the supporting block (216) in a rotationally symmetrical mode, a spring (215) is fixedly installed on the upper end face of the second supporting plate (210), a second screw rod (209) is sleeved inside the spring (215), a second screw rod (209) is fixedly installed on the partition plate (8) in a penetrating mode, a screw cap (214) is sleeved on the outer wall of the second screw rod (209), and the lower end face of the screw cap (214) is abutted to the spring (215).

When the filter plate (110) ascends or descends, the baffle plate (112) is driven to ascend or descend, the baffle plate (112) ascends to enable the feeding port (7) to be closed, the silicon micro powder in the storage bin (6) is prevented from falling, the baffle plate (112) descends, and the baffle plate (112) enables the feeding port (7) to be opened;

When the first screw rod (105) rotates, the first screw rod (105) drives the cam (201) to rotate, when the protruding portion of the cam (201) extrudes the fourth round rod (212), the cam (201) can drive the first round rod (104) to move upwards, the first round rod (104) drives the first screw rod (105) to ascend, the first screw rod (105) rotates in the second round rod (114) and moves upwards simultaneously, the first screw rod (105) drives the filter plate (110) to ascend through the threaded block (111), and when the protruding portion of the cam (201) does not extrude the fourth round rod (212), the filter plate (110) can naturally fall due to silicon micro powder and self gravity, and the filter plate (110) frequently shakes up and down in pure water.

2. The rinsing equipment for producing silica powder with a crushing mechanism according to claim 1, wherein: elevating system (100) are including servo motor (101), servo motor (101) up end fixed mounting is on second shell (5), and the output shaft fixed mounting of servo motor (101) has second belt pulley (106), second belt pulley (106) outside is from last first belt (103) and second belt (108) of overlapping down in proper order, first belt (103) are kept away from servo motor (101) one side inside cover and are equipped with first belt pulley (102), second belt (108) are kept away from servo motor (101) one side inside cover and are equipped with third belt pulley (107).

3. The rinsing equipment for producing silica powder with a crushing mechanism according to claim 2, wherein: the first belt pulley (102) and the third belt pulley (107) are rotatably mounted on the upper end surface of the first support plate (9).

4. The rinsing equipment for producing silica powder with a crushing mechanism according to claim 2, wherein: the first belt pulley (102) and the third belt pulley (107) are the same in size, and the second belt pulley (106) is twice as large as the first belt pulley (102).

5. A rinsing method for producing silica powder with a crushing mechanism, which adopts the rinsing equipment with the crushing mechanism for producing silica powder according to claim 1, and is characterized in that: the method comprises the following steps:

the first step: firstly, injecting a proper amount of pure water into the second housing (5), then, operating the control panel (2) to set related parameters, putting silicon micro powder into the second housing through the storage bin (6), driving the filter plate (110) to ascend or descend by the lifting mechanism (100), rinsing the silicon micro powder, and intermittently enabling the silicon micro powder in the storage bin (6) to enter the second housing (5); and a second step of: when the filter plate (110) rises or descends, the shaking component shakes the filter plate (110) to prevent the silicon micro powder from agglomerating, and when the filter plate (110) rises to the highest, the crushing roller (217) can crush the residual silicon micro powder on the filter plate (110), and the crushing degree is regulated by the regulating component.