CN115108056A - Ion cleaning type wind pressure touch type silicon carbide micro powder finished product packaging machine - Google Patents

Abstract

The invention discloses an ion cleaning type wind pressure touch type silicon carbide micro powder finished product packaging machine which comprises a pre-ion wind cleaning type rotary opening and closing type blanking assembly, a film supplying assembly, a one-way stepping type traction film sealing assembly and a two-way opposite-punching type film sealing and receiving assembly. The invention belongs to the technical field of silicon material finished product packaging, and aims to solve the problem that silicon carbide micro powder is easy to remain in a container to cause resource waste.

Description

Ion cleaning type wind pressure touch type silicon carbide micro powder finished product packaging machine

Technical Field

The invention belongs to the technical field of silicon material finished product packaging, and particularly relates to an ion cleaning type wind pressure touch type silicon carbide micro powder finished product packaging machine.

Background

The silicon carbide micro powder is an important raw material for preparing the silicon carbide wafer, and after the silicon carbide micro powder is produced, the finished silicon carbide micro powder needs to be packaged, but a plurality of problems exist in the specific packaging process. At present, when silicon carbide micro powder is packaged, a large amount of silicon carbide micro powder is often placed in a container, then blanking is controlled by using a control valve, when the storage capacity of the silicon carbide micro powder is overlarge, the liquidity of the silicon carbide micro powder is greatly reduced, in order to facilitate metering, the bottom size of the container is generally smaller, sometimes the silicon carbide micro powder can cause the blockage of the interior of the container, normal blanking can not be realized, the silicon carbide micro powder is easy to remain in the container, the more the amount of the silicon carbide micro powder is, the more the amount of the silicon carbide micro powder remains in the container, resource waste is easy to cause, the production cost is invisibly increased, meanwhile, in the packaging link, the packaging film is thinner, when the packaging film is longitudinally packaged, the left end and the right end of the packaging film are not easy to align, the packaging film on the outer side is easy to shift due to air resistance when the packaging film moves, and finally the packaging effect is not attractive, and the packaging film is thin, so that the packaging film is easy to deviate in the traction and conveying process, sometimes the packaging machine is blocked or fails, and the working efficiency of the packaging machine is seriously influenced, so that the problem is urgently solved by a silicon carbide micro-powder finished product packaging machine.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides an ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine, which solves various problems in the silicon carbide micro powder finished product packaging process.

The technical scheme adopted by the invention is as follows: the invention provides an ion-cleaning wind pressure touch type silicon carbide micro powder finished product packaging machine which comprises an ion wind-cleaning type rotary opening-closing type blanking assembly, wherein the ion wind-cleaning type rotary opening-closing type blanking assembly comprises an ion wind-cleaning type feeding device and a rotary opening-closing type blanking device, and the rotary opening-closing type blanking device is arranged at the bottom of the ion wind-cleaning type rotary opening-closing type blanking assembly; the membrane supply assembly is arranged below the ion wind cleaning type feeding device and comprises a supporting device and a driving device, and the driving device is arranged on the supporting device; the one-way stepping traction film sealing assembly is arranged below the rotary opening and closing type blanking device and comprises a rotary stepping traction device and an air pressure contact type longitudinal film sealing device, and the rotary stepping traction device is arranged above the air pressure contact type longitudinal film sealing device; and the bidirectional opposite-impact type film sealing and receiving assembly is arranged below the wind pressure abutting type longitudinal film sealing device and comprises a bidirectional opposite-impact type film sealing device and a nonlinear fluid receiving buffer device, and the nonlinear fluid receiving buffer device is arranged below the bidirectional opposite-impact type film sealing device.

As a preferable aspect of the present invention, wherein: the ion wind cleaning type feeding device comprises a top storage barrel, a storage barrel supporting arm, a feeding funnel, a spiral stirring motor, a spiral stirring shaft, an anti-blocking spiral sheet, a material conveying spiral sheet, an insulating shell, a cleaning fan, a wind hole, an insulating bushing, a discharging tip end and a wind inlet, wherein the storage barrel supporting arm is fixedly connected with two sides of the top storage barrel, the spiral stirring motor is arranged on the top wall of the top storage barrel, the spiral stirring shaft is arranged in the top storage barrel and is rotationally connected with the spiral stirring motor, the spiral stirring shaft penetrates through the top wall of the top storage barrel, the anti-blocking spiral sheet and the material conveying spiral sheet are spirally arranged on the spiral stirring shaft in a surrounding manner, the material conveying spiral sheet is arranged below the anti-blocking spiral sheet, the feeding funnel is arranged on one side of the spiral stirring motor, the insulating shell is arranged on the other side of the spiral stirring motor, and the wind hole is arranged on the top wall of the insulating shell, on the top inner wall of insulating casing was located to clean fan, the below of clean fan was located to insulating bushing, the below of insulating bushing is located to the point end of discharging, and the air intake runs through the roof of top storage vat, and the air intake is located under the insulating casing.

As a preferable aspect of the present invention, wherein: the rotary opening and closing type blanking device comprises a motor hanging bracket, an opening and closing driving motor, an opening and closing driving gear, a bottom wheel disc, gear teeth, an opening and closing piece, a first slide way, a top wheel disc, a second slide way, a hanging piece, a connecting shaft, a fixed shaft and a Z-shaped blanking pipe, wherein the bottom of the motor hanging bracket is sleeved on the opening and closing driving motor, the top of the motor hanging bracket is fixedly connected with a top material storage barrel, the opening and closing driving gear is arranged under the opening and closing driving motor, the opening and closing driving gear is rotatably connected with the opening and closing driving motor, the top wheel disc is fixedly connected with the bottom end of the top material storage barrel, two circles of the slide way are arranged on the top wheel disc, the opening and closing piece is arranged under the top wheel disc, the first slide way is arranged on the opening and closing piece, the bottom wheel disc is arranged under the opening and closing piece, the gear teeth are arranged on the bottom wheel disc, the gear teeth are meshed with the opening and closing driving gear, and the bottom end of the connecting shaft is rotatably connected with the bottom wheel disc, the top end of the connecting shaft is fixedly connected with the hanging piece, the connecting shaft penetrates through the opening and closing piece and the slide way II, the connecting shaft is rotatably connected with the opening and closing piece, the fixing shaft is arranged on the bottom wall of the top wheel disc in a surrounding mode and penetrates through the slide way I, and the bottom end of the fixing shaft is not in contact with the bottom wheel disc.

As a preferable aspect of the present invention, wherein: the supporting device comprises a supporting base, a first mounting plate and a second mounting plate, the first mounting plate and the second mounting plate are arranged on the supporting base, the first mounting plate and the second mounting plate are symmetrically arranged, the bottom end of the storage vat supporting arm is fixedly connected with the supporting base, and the first mounting plate and the second mounting plate are arranged between the storage vat supporting arms on two sides.

As a preferable aspect of the present invention, wherein: the driving device comprises a film supply motor, a traction roller, a film storage roller, a first tensioning roller and a second tensioning roller, the film supply motor is arranged on a first mounting plate, one end of the traction roller is rotatably connected with the film supply motor, the two ends of the traction roller are rotatably connected with the first mounting plate and the second mounting plate respectively, the film storage roller is arranged under the traction roller, the first tensioning roller is arranged in front of the traction roller, the second tensioning roller is arranged in front of the first tensioning roller, the height of the second tensioning roller is lower than that of the first tensioning roller, the film storage roller, the two ends of the first tensioning roller and the second tensioning roller are rotatably connected with the first mounting plate and the second mounting plate respectively.

As a preferable aspect of the present invention, wherein: the rotary stepping traction device comprises a first fixed sleeve plate, a connecting column, a second fixed sleeve plate, a former, an L-shaped connecting arm, a traction driving motor, a limiting shaft, a rotating disc, a limiting plate, a sliding chute, a C-shaped contact ring, a memory alloy bump and a sleeving and embedding disc, wherein the first fixed sleeve plate is sleeved on a Z-shaped blanking pipe, the first fixed sleeve plate and the Z-shaped blanking pipe are fixedly connected, the second fixed sleeve plate is arranged below the first fixed sleeve plate, the first fixed sleeve plate and the second fixed sleeve plate are connected through the connecting column, the former is fixedly connected on the second fixed sleeve plate, a gap is reserved between the second fixed sleeve plate and the former and the Z-shaped blanking pipe, the L-shaped connecting arm is arranged on a supporting arm of a storage barrel, the traction driving motor is arranged on the L-shaped connecting arm, the rotating shaft is rotatably connected with the traction driving motor, the limiting shaft is fixedly connected on the L-shaped connecting arm, the rotating disc is fixedly connected on the rotating shaft, the rotating disc is embedded in the sleeve embedding disc in a sleeved mode, the sleeve embedding disc and the rotating disc are in rotating connection, the limiting plate is fixedly connected to the sleeve embedding disc, the sliding groove is formed in one end of the limiting plate, the limiting shaft penetrates through the sliding groove, the C-shaped contact ring is fixedly connected to the sleeve embedding disc, and the memory alloy convex points are arranged on the peripheral curved surface of the C-shaped contact ring in a surrounding mode.

As a preferable aspect of the present invention, wherein: the wind pressure abutting type longitudinal film sealing device comprises a triangular connecting plate, a supporting transverse plate, a supporting vertical plate, a wind storage bin, an abutting fan, a wind pipe, a longitudinal sealing driving motor, a transmission shaft, a transmission wheel, a transmission belt, a first driving gear, a second driving gear, a rack plate, a longitudinal sealing strip, a connecting plate, a guide rod, a support rod and a guide sleeve ring, wherein the triangular connecting plate is arranged on a supporting arm of the storage bucket, two ends of the supporting transverse plate are respectively connected with the triangular connecting plates on two sides, the supporting vertical plate is arranged on the supporting transverse plate, the wind storage bin is arranged on the supporting transverse plate, the abutting fan is arranged on the top wall of the wind storage bin, the wind pipe is arranged on the side wall of the wind storage bin, the inner space of the wind storage bin is communicated with the wind pipe, the longitudinal sealing driving motor is arranged on the bottom wall of the supporting transverse plate, the transmission shaft is rotatably connected on the supporting transverse plate, the transmission shaft is provided with two groups, and the longitudinal sealing driving motor is rotatably connected with the transmission shaft on one side, the driving wheel is arranged on the driving shaft, the driving belt is sleeved on the driving wheel, the first driving gear is arranged on the driving shaft connected with the longitudinal sealing driving motor, the second driving gear is arranged on the driving shaft at the other side, the rack plate is arranged between the first driving gear and the second driving gear, the rack plate is respectively meshed and connected with the first driving gear and the second driving gear, the rack plate is provided with two groups, the first driving gear and the second driving gear are half gears, two ends of the rack plate are respectively connected with the connecting plate and the longitudinal sealing strip, the guide rods are arranged between the upper rack plate and the lower rack plate at equal intervals, one end of each guide rod is connected with the longitudinal sealing strip, the other end of each guide rod is connected with the connecting plate, each guide rod penetrates through the guide lantern ring, the guide rods are in sliding connection with the guide lantern ring, the support rods are symmetrically arranged at two sides of the guide lantern ring, and one end of each support rod is fixedly connected with the guide lantern ring, the other end of the supporting rod is fixedly connected with the supporting vertical plate.

As a preferable aspect of the present invention, wherein: the bidirectional opposite-punching type film sealing device comprises a film sealing connecting arm, a U-shaped supporting plate, a mounting block, a sliding rod, a connecting cross rod I, a connecting cross rod II, a connecting cross rod III, a cross seal strip, a cutting blade, a cross seal driving motor, a cross seal gear, a partition plate, a driving disc and a swinging rod, wherein one end of the film sealing connecting arm is connected with a supporting arm of a storage barrel, the other end of the film sealing connecting arm is connected with the side wall of the U-shaped supporting plate, the cross seal driving motor is arranged on the bottom wall of the U-shaped supporting plate, the mounting block is arranged on the side wall of the U-shaped supporting plate, the sliding rod penetrates through the mounting block, the sliding rod is in sliding connection with the mounting block, one end of the sliding rod is in fixed connection with the connecting cross rod II, the other end of the sliding rod is in fixed connection with the connecting cross rod II, the connecting cross rod III is arranged between the connecting cross rod I and the connecting cross rod II, the connecting cross rod III is in sliding connection with the sliding rod, the cross seal gear is rotatably connected with the U-shaped supporting plate, the horizontal seal gear is equipped with two sets ofly, horizontal seal driving motor keeps rotating with the horizontal seal gear of one side and is connected, the baffle is located on the horizontal seal gear, the driving-disc rotates to be connected and locates on the baffle, the axial region of driving-disc keeps fixed connection with the axial region of horizontal seal gear, the one end of swinging arms rotates to be connected and locates on the driving-disc, the swinging arms on the driving-disc of horizontal seal driving motor top keeps rotating between three with being connected the horizontal pole and is connected, the swinging arms of opposite side keeps rotating with being connected horizontal pole one and is connected, horizontal seal strip symmetrical arrangement locates respectively on connecting horizontal pole two and connecting horizontal pole three, cutting blade locates in the recess on the horizontal seal strip.

As a preferable aspect of the present invention, wherein: the nonlinear fluid receiving buffer device comprises a mounting vertical plate, a shock absorber, a bearing plate and a nonlinear fluid bearing bag, wherein the mounting vertical plate is arranged on the supporting base, the top end of the bearing plate is hinged with the mounting vertical plate, the bottom end of the shock absorber is hinged with the mounting vertical plate, the top end of the shock absorber is hinged with the bearing plate, the nonlinear fluid bearing bag is arranged on the mounting vertical plate, and the nonlinear fluid bearing bag is filled with nonlinear fluid.

As a preferable aspect of the present invention, wherein: the C-shaped contact rings are symmetrically arranged on two sides of the Z-shaped blanking pipe.

Preferably, a central controller is arranged on the supporting base to assist in achieving the functions of material conveying, loading, packaging and the like, and the model of the central controller is STC12C 6082.

The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine provided by the invention has the following beneficial effects:

(1) aiming at the problem that the silicon carbide micro powder is easy to remain in the container to cause resource waste, the invention is based on the technical principle of intermedium and curved surface, the cleaning fan and the discharge tip are utilized to form ion wind flow, and the ion wind flow flows downwards along the spiral curved surface formed by the anti-blocking spiral piece after entering the top storage barrel, so that on one hand, the ion wind flow can play a role of quickly blowing away the silicon carbide micro powder, on the other hand, the curved spiral channel can increase the contact area between the ion wind flow and the inner space of the top storage barrel, the cleaning effect is greatly improved, workers do not need to manually clean, and the waste of the silicon carbide micro powder resource is effectively reduced.

(2) Aiming at the problem that a large amount of silicon carbide micro powder can cause the blockage inside a container, the invention is based on the technical principle of dynamic characteristics, when the blockage occurs inside a top storage barrel, a spiral stirring motor is utilized to drive an anti-blocking spiral sheet and a material conveying spiral sheet to rotate, at the moment, the silicon carbide micro powder inside the top storage barrel is firstly conveyed upwards, then the spiral stirring motor rotates reversely, the silicon carbide micro powder is driven to move downwards again, the anti-blocking effect can be achieved, and the material conveying spiral sheet can achieve the effect of quantitatively conveying the silicon carbide micro powder.

(3) Aiming at the problem that the packaging film on the outer side of the longitudinal packaging link is easy to deviate due to air resistance when moving, based on the technical principles of reverse action, air pressure and a hydraulic structure, before the packaging film is longitudinally packaged, an air flow is generated by a butting fan and flows out through an air pipe, the end part of the packaging film on the outer side is tightly pressed and covered on the end part of the packaging film on the inner side along the direction forming an included angle of 45 degrees with a longitudinal sealing strip, so that the packaging films on the two ends are aligned, and then the longitudinal sealing strip is used for longitudinally packaging the packaging film.

(4) After the carborundum miropowder packing finishes, can drop on nonlinear fluid pressure-bearing bag from the top down, nonlinear fluid pressure-bearing bag received instantaneous impact effect this moment, can produce the support effect of solid, and carborundum miropowder wrapping bag lies in nonlinear fluid pressure-bearing bag when bumping in addition, and the noise of production is little, when being applied to large-scale baling line, can effectively reduce indoor noise.

(5) Indulge and seal driving motor and drive gear one and drive gear two syntropy and rotate, when drive gear one and rack plate meshing, can drive rack plate and remove towards the direction of being close to Z type unloading pipe, when drive gear one will break away from rack plate, drive gear two and rack plate produce the meshing relation, drive gear two this moment drive rack plate and remove towards the direction of keeping away from Z type unloading pipe to finally drive the strip of paper used for sealing reciprocating motion all around, vertically encapsulate to the packaging film in succession.

(6) The horizontal sealing driving motor drives the two horizontal sealing gears to rotate along opposite directions, the horizontal sealing gears drive the two driving discs to rotate along opposite directions, the driving discs drive the connecting cross rods I and the connecting cross rods III to do reciprocating relative motion and opposite motion through the swinging rods, the distances between the connecting cross rods I and the connecting cross rods III are periodically reduced and increased, and the distances between the connecting cross rods II and the connecting cross rods I are fixed, so that the distances between the connecting cross rods II and the connecting cross rods III are also periodically reduced and increased.

(7) When traction drive motor drives the axis of rotation and rotates, the axis of rotation drives the rolling disc and rotates, because the rolling disc keeps rotating with set and inlays between the dish and be connected, including the limiting displacement of spacing axle and spout, when leading to the rolling disc upwards to rotate, set inlays the dish and upwards rotates round spacing axle on one side, move towards the direction of being close to Z type unloading pipe on one side again, and when the rolling disc rotates downwards, set inlays the dish and downwards rotates round spacing axle on one side, move towards the direction of keeping away from Z type unloading pipe on one side again, when C type contact ring on this in-process set bumped the packaging film on the Z type unloading pipe, can drive packaging film and move downwards, memory alloy bump on the C type contact ring can utilize the shape memory characteristic of self simultaneously, greatly prolong the life of C type contact ring, reduce the wearing and tearing of C type contact ring.

Drawings

Fig. 1 is a schematic view of the overall structure of an ion-cleaning wind pressure collision type silicon carbide micro powder finished product packaging machine provided by the invention;

FIG. 2 is a schematic view of the overall structure of the ion wind cleaning type rotary opening and closing type blanking assembly according to the present invention;

FIG. 3 is a schematic view of the overall structure of the ion wind cleaning type feeding device according to the present invention;

fig. 4 is a sectional view of an insulation case according to the present invention;

fig. 5 is a schematic view of the overall structure of the rotary opening and closing type blanking device provided by the invention;

FIG. 6 is a schematic view of the overall structure of the opening/closing sheet according to the present invention;

fig. 7 is an exploded view of a rotary opening and closing type blanking device according to the present invention;

FIG. 8 is a schematic view of the overall structure of a membrane supply module according to the present invention;

fig. 9 is a schematic view of the overall structure of the rotary stepping traction device according to the present invention;

FIG. 10 is a schematic view of the overall structure of the forming device according to the present invention;

fig. 11 is a schematic view of the overall structure of a C-shaped contact ring according to the present invention;

FIG. 12 is a schematic view of the overall structure of the wind pressure contact type longitudinal film sealing device according to the present invention;

fig. 13 is a schematic view of the overall structure of the support rod according to the present invention;

FIG. 14 is a schematic view of the overall structure of the two-way opposite-punching type film sealing device according to the present invention;

FIG. 15 is a cross-sectional view of a bi-directional impact sealing film device according to the present invention;

fig. 16 is a schematic view of the overall structure of the nonlinear fluid receiving buffer device according to the present invention;

fig. 17 is a schematic block diagram of an ion-cleaning wind pressure collision type silicon carbide micro powder finished product packaging machine provided by the invention;

fig. 18 is a module circuit diagram of an ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to the present invention;

fig. 19 is a motor driving circuit diagram of an ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to the present invention.

Wherein, 1, the ionic wind cleaning type rotary open-close type blanking component, 11, the ionic wind cleaning type feeding device, 110, a top storage tank, 111, a storage tank supporting arm, 112, a feeding funnel, 113, a spiral stirring motor, 114, a spiral stirring shaft, 115, an anti-blocking spiral sheet, 116, a material conveying spiral sheet, 117, an insulating shell, 118, a cleaning fan, 119, an air hole, 1110, an insulating bushing plate, 1111, a discharge tip, 1112, an air inlet, 12, the rotary open-close type blanking device, 120, a motor hanger, 121, an open-close driving motor, 122, an open-close driving gear, 123, a bottom wheel disc, 124, gear teeth, 125, an open-close sheet, 126, a first slideway, 127, a top wheel disc, 128, a second slideway, 129, a hanging sheet, 1210, a connecting shaft, 1211, a fixed shaft, 1212, a Z-type blanking pipe, 2, a film feeding component, 21, a supporting device, 210, a supporting base, 211 and a first mounting plate, 212. a second mounting plate, 22, a driving device, 220, a film supply motor, 221, a traction roller, 222, a film storage roller, 223, a first tensioning roller, 224, a second tensioning roller, 3, a unidirectional stepping traction film sealing component, 31, a rotating stepping traction device, 310, a first fixed sleeve plate, 311, a connecting column, 312, a second fixed sleeve plate, 313, a former, 314, an L-shaped connecting arm, 315, a traction driving motor, 316, a limiting shaft, 317, a rotating shaft, 318, a rotating disc, 319, a limiting plate, 3110, a chute, 3111, a C-shaped contact ring, 3112, a memory alloy bump, 3113, a nested disc, 32, a wind pressure contact type longitudinal film sealing device, 320, a triangular connecting plate, 321, a supporting transverse plate, 322, a supporting vertical plate, 323, a wind storage bin, 324, a collision fan, 325, a wind pipe, 326, a longitudinal sealing driving motor, a transmission shaft, 329, 328, a transmission wheel, a transmission belt, 3210 and a first driving gear, 3211. the device comprises a second driving gear 3212, a rack plate 3213, a longitudinal sealing strip 3214, a connecting plate 3215, a guide rod 3216, a support rod 3217, a guide sleeve ring 4, a two-way opposite-flushing type film sealing and receiving component 41, a two-way opposite-flushing type film sealing device 410, a film sealing and connecting arm 411, a U-shaped supporting plate 412, a mounting block 413, a sliding rod 414, a first connecting cross rod 415, a second connecting cross rod 416, a third connecting cross rod 417, a transverse sealing strip 418, a cutting blade 419, a transverse sealing driving motor 4110, a transverse sealing gear 4111, a partition plate 4112, a driving disk 4113, a swinging rod 42, a nonlinear fluid receiving buffer device 420, a mounting vertical plate 421, a shock absorber 422, a pressure bearing plate 423 and a nonlinear fluid pressure bearing bag.

In the circuit diagram of the central controller in fig. 18, +5V is the power supply of the circuit, GND is the ground terminal, XTAL1 is the crystal oscillator, C1 and C2 are the oscillation starting capacitors of the crystal oscillator, P1 is the connection port of the helical agitator motor and the central controller, P2 is the connection port of the opening and closing drive motor and the central controller, P3 is the connection port of the film supply motor and the central controller, P4 is the connection port of the traction drive motor and the central controller, P5 is the connection port of the longitudinal seal drive motor and the central controller, and P6 is the connection port of the transverse seal drive motor and the central controller; in the motor driving circuit diagram of fig. 19, BTS7970B is a dc motor driving chip, R1 to R10 are resistors, C3 and C4 are filter capacitors, D1 and D2 are diodes, and a motor is a motor.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As a new embodiment of the present invention, as shown in fig. 1, the present invention provides an ion-cleaning wind pressure-conflicting type silicon carbide micropowder finished product packaging machine, which includes an ion wind-cleaning type rotary opening and closing type blanking assembly 1, wherein the ion wind-cleaning type rotary opening and closing type blanking assembly 1 includes an ion wind-cleaning type feeding device 11 and a rotary opening and closing type blanking device 12, and the rotary opening and closing type blanking device 12 is disposed at the bottom of the ion wind-cleaning type rotary opening and closing type blanking assembly 1; the membrane supply assembly 2 is arranged below the ion wind cleaning type feeding device 11, the membrane supply assembly 2 comprises a supporting device 21 and a driving device 22, and the driving device 22 is arranged on the supporting device 21; the one-way stepping traction film sealing component 3 is arranged below the rotary opening and closing type blanking device 12, the one-way stepping traction film sealing component 3 comprises a rotary stepping traction device 31 and an air pressure contact type longitudinal film sealing device 32, and the rotary stepping traction device 31 is arranged above the air pressure contact type longitudinal film sealing device 32; and the bidirectional opposite-flushing type film sealing and receiving assembly 4 is arranged below the wind pressure abutting type longitudinal film sealing device 32, the bidirectional opposite-flushing type film sealing and receiving assembly 4 comprises a bidirectional opposite-flushing type film sealing device 41 and a nonlinear fluid receiving buffer device 42, and the nonlinear fluid receiving buffer device 42 is arranged below the bidirectional opposite-flushing type film sealing device 41.

As shown in fig. 2-4, the ion wind clean feeder 11 includes a top storage bin 110, a storage bin supporting arm 111, a feeding funnel 112, a spiral stirring motor 113, a spiral stirring shaft 114, an anti-blocking spiral blade 115, a feeding spiral blade 116, an insulating shell 117, a cleaning fan 118, an air hole 119, an insulating leakage plate 1110, a discharge tip 1111 and an air inlet 1112, wherein the storage bin supporting arm 111 is fixedly connected to both sides of the top storage bin 110, the spiral stirring motor 113 is disposed on the top wall of the top storage bin 110, the spiral stirring shaft 114 is disposed in the top storage bin 110, the spiral stirring shaft 114 is rotatably connected to the spiral stirring motor 113, the spiral stirring shaft 114 passes through the top wall of the top storage bin 110, the anti-blocking spiral blade 115 and the feeding spiral blade 116 are spirally disposed on the spiral stirring shaft 114, the feeding spiral blade 116 is disposed below the anti-blocking spiral blade 115, the feeding funnel 112 is disposed on one side of the spiral stirring motor 113, insulating casing 117 locates spiral agitator motor 113's opposite side, and on wind hole 119 located the roof of insulating casing 117, clean fan 118 located the top inner wall of insulating casing 117, insulating bushing 1110 located the below of clean fan 118, and the below of insulating bushing 1110 is located to discharge point 1111, and air intake 1112 runs through the roof of top storage vat 110, and air intake 1112 locates insulating casing 117 directly below.

As shown in fig. 2, 5, 6 and 7, the rotary open-close type blanking device 12 includes a motor hanger 120, an open-close driving motor 121, an open-close driving gear 122, a bottom wheel disc 123, a gear 124, an open-close piece 125, a first slideway 126, a top wheel disc 127, a second slideway 128, a hanging piece 129, a connecting shaft 1210, a fixing shaft 1211 and a Z-shaped blanking pipe 1212, wherein the bottom of the motor hanger 120 is sleeved on the open-close driving motor 121, the top of the motor hanger 120 is fixedly connected with the top storage barrel 110, the open-close driving gear 122 is arranged right below the open-close driving motor 121, the open-close driving gear 122 is rotatably connected with the open-close driving motor 121, the top wheel disc 127 is fixedly connected to the bottom end of the top storage barrel 110, the second slideway 128 is arranged around the top wheel disc 127, the open-close piece 125 is arranged below the top wheel disc 127, the first slideway 126 is arranged on the open-close piece 125, the bottom wheel disc 123 is arranged below the open-close piece 125, the gear teeth 124 are arranged on the bottom wheel disc 123, the gear teeth 124 are meshed and connected with the opening and closing driving gear 122, the bottom end of the connecting shaft 1210 is rotatably connected with the bottom wheel disc 123, the top end of the connecting shaft 1210 is fixedly connected with the hanging piece 129, the connecting shaft 1210 penetrates through the opening and closing piece 125 and the slide way II 128, the connecting shaft 1210 is rotatably connected with the opening and closing piece 125, the fixing shaft 1211 is arranged on the bottom wall of the top wheel disc 127 in a surrounding mode, the fixing shaft 1211 penetrates through the slide way I126, and the bottom end of the fixing shaft 1211 is not in contact with the bottom wheel disc 123.

As shown in fig. 8, the supporting device 21 includes a supporting base 210, a first mounting plate 211 and a second mounting plate 212, the first mounting plate 211 and the second mounting plate 212 are disposed on the supporting base 210, the first mounting plate 211 and the second mounting plate 212 are symmetrically disposed, the bottom ends of the storage tank supporting arms 111 are fixedly connected to the supporting base 210, and the first mounting plate 211 and the second mounting plate 212 are disposed between the storage tank supporting arms 111 on both sides.

As shown in fig. 8, the driving device 22 includes a film supply motor 220, a drawing roller 221, a film storage roller 222, a first tensioning roller 223 and a second tensioning roller 224, the film supply motor 220 is disposed on the first mounting plate 211, one end of the drawing roller 221 is rotatably connected with the film supply motor 220, two ends of the drawing roller 221 are rotatably connected with the first mounting plate 211 and the second mounting plate 212 respectively, the film storage roller 222 is disposed right below the drawing roller 221, the first tensioning roller 223 is disposed right in front of the drawing roller 221, the second tensioning roller 224 is disposed in front of the first tensioning roller 223, the height of the second tensioning roller 224 is lower than that of the first tensioning roller 223, and two ends of the film storage roller 222, the first tensioning roller 223 and the second tensioning roller 224 are rotatably connected with the first mounting plate 211 and the second mounting plate 212 respectively.

As shown in fig. 9-11, the rotary stepping traction device 31 includes a first fixed sleeve plate 310, a connecting column 311, a second fixed sleeve plate 312, a former 313, an L-shaped connecting arm 314, a traction driving motor 315, a limiting shaft 316, a rotating shaft 317, a rotating disc 318, a limiting plate 319, a chute 3110, a C-shaped contact ring 3111, a memory alloy bump 3112 and an embedding disc 3113, wherein the first fixed sleeve plate 310 is sleeved on the Z-shaped blanking tube 1212, the first fixed sleeve plate 310 is fixedly connected with the Z-shaped blanking tube 1212, the second fixed sleeve plate 312 is disposed below the first fixed sleeve plate 310, the first fixed sleeve plate 310 is connected with the second fixed sleeve plate 312 through the connecting column 311, the former 313 is fixedly connected with the second fixed sleeve plate 312, a gap is left between the second fixed sleeve plate 312 and the former 313 and the Z-shaped blanking tube 1212, the L-shaped connecting arm 314 is disposed on the storage barrel 111, the support arm 315 of the traction driving motor is disposed on the L-shaped connecting arm 314, the rotating shaft 317 is rotatably connected with the traction drive motor 315, the limiting shaft 316 is fixedly connected to the L-shaped connecting arm 314, the rotating disc 318 is fixedly connected to the rotating shaft 317, the rotating disc 318 is nested in the nested disc 3113, the nested disc 3113 is rotatably connected to the rotating disc 318, the limiting plate 319 is fixedly connected to the nested disc 3113, the sliding slot 3110 is arranged at one end of the limiting plate 319, the limiting shaft 316 penetrates through the sliding slot 3110, the C-shaped contact ring 3111 is fixedly connected to the nested disc 3113, and the memory alloy bumps 3112 are arranged around the peripheral curved surface of the C-shaped contact ring 3111.

As shown in fig. 12 and 13, the wind pressure contact type longitudinal film sealing device 32 includes a triangular connecting plate 320, a supporting horizontal plate 321, a supporting vertical plate 322, a wind storage bin 323, a contact fan 324, a wind pipe 325, a longitudinal sealing driving motor 326, a transmission shaft 327, a transmission wheel 328, a transmission belt 329, a first driving gear 3210, a second driving gear 3211, a rack plate 3212, a longitudinal sealing strip 3213, a connecting plate 3214, a guide rod 3215, a support rod 3216 and a guide collar 3217, the triangular connecting plate 320 is disposed on the storage bin supporting arm 111, two ends of the supporting horizontal plate 321 are respectively connected with the triangular connecting plates 320 on two sides, the supporting vertical plate 322 is disposed on the supporting horizontal plate 321, the wind storage bin 323 is disposed on the supporting horizontal plate 321, the contact fan 324 is disposed on a top wall of the wind storage bin 323, 325 is disposed on a side wall of the wind storage bin 323, an inner space of the wind storage bin 323 is communicated with the wind pipe 325, the longitudinal sealing driving motor 326 is disposed on a bottom wall of the supporting horizontal plate 321, the transmission shafts 327 are rotatably connected with the supporting transverse plate 321, two groups of transmission shafts 327 are provided, the longitudinal sealing driving motor 326 is rotatably connected with the transmission shaft 327 on one side, the transmission wheel 328 is provided on the transmission shaft 327, the transmission belt 329 is sleeved on the transmission wheel 328, the first driving gear 3210 is arranged on the transmission shaft 327 connected with the longitudinal sealing driving motor 326, the second driving gear 3211 is arranged on the transmission shaft 327 on the other side, the rack plates 3212 are arranged between the first driving gear 3210 and the second driving gear 3211, the rack plates 3212 are respectively engaged with the first driving gear 3210 and the second driving gear 3211, the two groups of rack plates 3212 are provided, the first driving gear 3210 and the second driving gear 3211 are half gears, two ends of the rack plates 3212 are respectively connected with the connecting plate 3214 and the longitudinal sealing strip 3213, the guide rods 3215 are equally spaced between the upper and lower rack plates 3212, one end of the guide rod 3215 is connected with the longitudinal sealing strip 3213, the other end of the guide rod 5 is connected with the connecting plate 3214, the guide rod 3215 penetrates through the guide lantern ring 3217, the guide rod 3215 and the guide lantern ring 3217 are slidably connected, the support rods 3216 are symmetrically arranged on two sides of the guide lantern ring 3217, one end of each support rod 3216 is fixedly connected with the guide lantern ring 3217, and the other end of each support rod 3216 is fixedly connected with the support vertical plate 322.

As shown in fig. 14 and 15, the bidirectional hedging sealing device 41 includes a sealing film connecting arm 410, a U-shaped supporting plate 411, a mounting block 412, a sliding rod 413, a first connecting cross bar 414, a second connecting cross bar 415, a third connecting cross bar 416, a horizontal sealing strip 417, a cutting blade 418, a horizontal sealing driving motor 419, a horizontal sealing gear 4110, a partition plate 4111, a driving disk 4112 and a swinging rod 4113, wherein one end of the sealing film connecting arm 410 is connected to the storage vat supporting arm 111, the other end of the sealing film connecting arm 410 is connected to a side wall of the U-shaped supporting plate 411, the horizontal sealing driving motor 419 is disposed on the bottom wall of the U-shaped supporting plate 411, the mounting block 412 is disposed on the side wall of the U-shaped supporting plate 411, the sliding rod 413 passes through the mounting block 412, the sliding rod 413 is slidably connected to the mounting block 412, one end of the sliding rod 413 is fixedly connected to the first connecting cross bar 414, the other end of the sliding rod 413 is fixedly connected to the second connecting cross bar 415, the third connecting cross bar 416 is disposed between the first connecting cross bar 414 and the second connecting cross bar 415, the connecting cross bar III 416 is in sliding connection with the sliding rod 413, the cross sealing gear 4110 is rotatably connected to the U-shaped supporting plate 411, two sets of cross sealing gears 4110 are provided, the cross sealing driving motor 419 is rotatably connected to the cross sealing gear 4110 on one side, the partition plate 4111 is provided on the cross sealing gear 4110, the driving plate 4112 is rotatably connected to the partition plate 4111, the shaft of the driving plate 4112 is fixedly connected to the shaft of the cross sealing gear 4110, one end of the oscillating rod 4113 is rotatably connected to the driving plate 4112, the oscillating rod 4113 on the driving plate 4112 above the cross sealing driving motor 419 is rotatably connected to the connecting cross bar III 416, the oscillating rod 4113 on the other side is rotatably connected to the connecting cross bar I414, the cross sealing bars 417 are symmetrically arranged on the connecting cross sealing bars II 415 and the connecting cross sealing bar III 416, and the cutting blades 418 are arranged in grooves on the cross sealing bar 417.

As shown in fig. 16, the nonlinear fluid receiving buffer device 42 includes an installation vertical plate 420, a shock absorber 421, a pressure-bearing plate 422 and a nonlinear fluid pressure-bearing bag 423, the installation vertical plate 420 is disposed on the support base 210, a top end of the pressure-bearing plate 422 is hinged to the installation vertical plate 420, a bottom end of the shock absorber 421 is hinged to the installation vertical plate 420, a top end of the shock absorber 421 is hinged to the pressure-bearing plate 422, the nonlinear fluid pressure-bearing bag 423 is disposed on the installation vertical plate 420, and the nonlinear fluid pressure-bearing bag 423 is filled with nonlinear fluid.

As shown in fig. 9, C-shaped contact rings 3111 are symmetrically disposed on both sides of the Z-shaped blanking tube 1212.

Preferably, a central controller is arranged on the support base 210 to assist in realizing the functions of material conveying, loading, packaging and the like, and the model of the central controller is STC12C 6082.

When the device is used, a user pours the prepared silicon carbide micro powder into the top storage barrel 110 through the feeding hopper 112, winds and winds a packaging film on the film storage roller 222, then pulls the packaging film to enable the packaging film to sequentially pass through the traction roller 221, the first tensioning roller 223 and the second tensioning roller 224, plugs the packaging film into a gap between the former 313 and the Z-shaped blanking tube 1212, after the packaging film passes through the former 313, the packaging film starts the abutting fan 324 to generate air flow, the air flow flows out through the air pipe 325, the end part of the packaging film on the outer side is tightly pressed and covered on the end part of the packaging film on the inner side along the direction forming an included angle of 45 degrees with the longitudinal sealing strip 3213 to enable the packaging films on the two ends to be aligned, then the longitudinal sealing driving motor 326 is started, the longitudinal sealing driving motor 326 drives the first driving gear 3210 and the second driving gear 3211 to rotate in the same direction, and when the first driving gear 3210 is meshed with the rack plate, the rack plate 3212 can be driven to move towards the direction close to the Z-shaped blanking tube 3211212, when the first driving gear 3210 is about to be disengaged from the rack plate 3212, the second driving gear 3211 engages with the rack plate 3212, and at this time, the second driving gear 3211 drives the rack plate 3212 to move in a direction away from the Z-shaped blanking tube 1212, so as to finally drive the longitudinal seal 3213 to reciprocate back and forth, longitudinally seal the packaging film, and then continue to pull the packaging film downward, and when the bottom of the packaging film is located between the transverse seal strips 417 on both sides, the transverse seal driving motor 419 is started, the transverse seal driving motor 419 drives the two transverse seal gears 4110 to rotate in opposite directions, the transverse seal gears 4110 drive the two driving disks 4112 to rotate in opposite directions, the driving disks 4112 drive the first connecting cross bar 414 and the third connecting cross bar 416 to do reciprocating relative motion and opposite motion, and the distance between the first connecting cross bar 414 and the third connecting cross bar 416 is periodically decreased and increased, because the distance between the connecting cross bar II 415 and the connecting cross bar I414 is fixed, the distance between the connecting cross bar II 415 and the connecting cross bar III 416 is also periodically reduced and increased, when the distance between the connecting cross bar II 415 and the connecting cross bar III 416 is reduced, the horizontal seal 417 can transversely seal the packaging film, the bottom and the side of the packaging film are sealed, the packaging film is continuously pulled downwards, the moving distance of the packaging film is consistent with the preset length of the packaging bag, then the opening and closing driving motor 121 is started, the opening and closing driving motor 121 drives the opening and closing driving gear 122 to rotate clockwise, the opening and closing driving gear 122 drives the bottom wheel disc 123 to rotate anticlockwise, the bottom wheel disc 123 firstly drives the opening and closing piece 125 to rotate around the connecting shaft 1210 when rotating, but due to the limiting effect of the fixing shaft 1211 and the adjacent opening and closing piece 125, relative sliding can be generated between the opening and closing pieces 125, the contact area between the opening and closing pieces 125 is reduced, the opening and closing pieces 125 are gradually dispersed to the periphery, so that the silicon carbide micro powder in the top storage barrel 110 smoothly falls into the Z-shaped blanking pipe 1212 and finally falls into the lower packaging film with the bottom sealed and the edge sealed, then the transverse sealing driving motor 419 is started to drive the transverse sealing strip 417 and the cutting blade 418 to seal and cut the packaging film, the packaging film is formed into a packaging bag after being sealed, the top of the packaging bag is cut by the cutting blade 418 and then separated from the packaging film to fall onto the nonlinear fluid pressure-bearing bag 423, at the moment, the nonlinear fluid pressure-bearing bag 423 is subjected to instantaneous impact, a solid supporting effect can be generated, and when the silicon carbide micro powder packaging bag is collided with the nonlinear fluid pressure-bearing bag 423, the generated noise is small, and when the silicon carbide micro powder packaging bag is applied to a large-scale packaging line, the indoor noise can be effectively reduced; the following packaging process can be repeated, at this time, the packaging bag does not need to be pulled manually by a worker, the traction drive motor 315 is used for driving the rotating shaft 317 to rotate, the rotating shaft 317 drives the rotating disc 318 to rotate, the sleeve embedding disc 3113 moves towards the direction close to the Z-shaped blanking tube 1212 while rotating upwards around the limiting shaft 316 due to the rotation connection between the rotating disc 318 and the sleeve embedding disc 3113 and the limiting effect of the limiting shaft 316 and the sliding chute 3110, and when the rotating disc 318 rotates downwards, the sleeve embedding disc 3113 moves away from the Z-shaped blanking tube 1212 while rotating downwards around the limiting shaft 316 while rotating downwards, in the process, when the C-shaped contact ring 3111 on the sleeve embedding disc 3113 touches the packaging film on the Z-shaped blanking tube 1212, the packaging film can be driven to move downwards, and meanwhile, the memory alloy salient points 3112 on the C-shaped contact ring 3111 can utilize the shape memory characteristics of the self, the service life of the C-shaped contact ring 3111 is greatly prolonged, the abrasion of the C-shaped contact ring 3111 is reduced, and the film motor 220 is started together when the traction drive motor 315 is started, so that the traction resistance is reduced; after packaging is finished, when a large amount of silicon carbide micro powder still remains in the top storage barrel 110, the cleaning fan 118 and the discharge tip 1111 are utilized to form an ion wind flow, and after the ion wind flow enters the top storage barrel 110, the ion wind flow flows downwards along a spiral curve formed by the anti-blocking spiral sheet 115, so that on one hand, the ion wind flow can play a role of quickly blowing away the silicon carbide micro powder, on the other hand, a curved spiral channel can increase the contact area between the ion wind flow and the inner space of the top storage barrel 110, the cleaning effect is greatly improved, workers do not need to clean the silicon carbide micro powder manually, and the waste of silicon carbide micro powder resources is effectively reduced; when the top storage barrel 110 is blocked due to the fact that the size of the silicon carbide micro powder is too large, the spiral stirring motor 113 is started, the spiral stirring motor 113 drives the anti-blocking spiral piece 115 and the material conveying spiral piece 116 to rotate, at the moment, the silicon carbide micro powder in the top storage barrel 110 is conveyed upwards firstly, then the spiral stirring motor 113 rotates reversely, the silicon carbide micro powder is driven to move downwards again, the anti-blocking effect can be achieved, the material conveying spiral piece 116 can achieve the effect of quantitatively conveying the silicon carbide micro powder, the whole working process is the whole working process, and the steps can be repeated when the silicon carbide micro powder is used next time.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides an ion cleaning formula wind pressure conflict type carborundum miropowder finished product packagine machine which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the device comprises an ion wind cleaning type rotary opening-closing type blanking assembly (1), wherein the ion wind cleaning type rotary opening-closing type blanking assembly (1) comprises an ion wind cleaning type feeding device (11) and a rotary opening-closing type blanking device (12), and the rotary opening-closing type blanking device (12) is arranged at the bottom of the ion wind cleaning type rotary opening-closing type blanking assembly (1);

the membrane supply assembly (2) is arranged below the ion wind cleaning type feeding device (11), the membrane supply assembly (2) comprises a supporting device (21) and a driving device (22), and the driving device (22) is arranged on the supporting device (21);

the one-way stepping type traction film sealing assembly (3) is arranged below the rotary opening and closing type blanking device (12), the one-way stepping type traction film sealing assembly (3) comprises a rotary stepping type traction device (31) and an air pressure contact type longitudinal film sealing device (32), and the rotary stepping type traction device (31) is arranged above the air pressure contact type longitudinal film sealing device (32); and the number of the first and second groups,

two-way offset type is sealed the membrane and is connect material subassembly (4), two-way offset type is sealed the membrane and is connect material subassembly (4) to locate the below that the wind pressure supported the vertical membrane device (32) that seals of formula, two-way offset type is sealed the membrane and is connect material subassembly (4) to include two-way offset type to seal membrane device (41) and nonlinear fluid and connect material buffer (42), nonlinear fluid connects material buffer (42) to locate two-way offset type and seals the below of membrane device (41).

2. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 1, which is characterized in that: clean formula feedway of ion wind (11) include top storage vat (110), storage vat support arm (111), feed hopper (112), spiral agitator motor (113), spiral (mixing) shaft (114), prevent blocking flight (115), defeated flight (116), insulating casing (117), clean fan (118), wind hole (119), insulating bushing (1110), discharge pointed end (1111) and air intake (1112), the both sides of top storage vat (110) are located to storage vat support arm (111) fixed connection, spiral agitator motor (113) are located on the roof of top storage vat (110), spiral (mixing) shaft (114) are located in top storage vat (110), spiral (mixing) shaft (114) and spiral agitator motor (113) keep rotating to be connected, spiral (mixing) shaft (114) pass the roof of top storage vat (110), prevent that spiral (mixing) shaft (115) and defeated flight (116) spiral encircle to arrange and locate spiral (114) (mixing) spiral (114) ) On, defeated material flight (116) are located and are prevented the below of blocking flight (115), one side of spiral agitator motor (113) is located in feed hopper (112), the opposite side of spiral agitator motor (113) is located in insulating shell (117), wind hole (119) are located on the roof of insulating shell (117), clean fan (118) are located on the top inner wall of insulating shell (117), the below of clean fan (118) is located in insulating bushing (1110), the below of insulating bushing (1110) is located in discharge point (1111), air intake (1112) run through the roof of top storage vat (110), air intake (1112) are located under insulating shell (117).

3. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 2, which is characterized in that: the rotary opening and closing type blanking device (12) comprises a motor hanging frame (120), an opening and closing driving motor (121), an opening and closing driving gear (122), a bottom wheel disc (123), gear teeth (124), an opening and closing piece (125), a first slideway (126), a top wheel disc (127), a second slideway (128), a hanging piece (129), a connecting shaft (1210), a fixing shaft (1211) and a Z-shaped blanking pipe (1212), wherein the bottom of the motor hanging frame (120) is sleeved on the opening and closing driving motor (121), the top of the motor hanging frame (120) is fixedly connected with a top material storage barrel (110), the opening and closing driving gear (122) is arranged under the opening and closing driving motor (121), the opening and closing driving gear (122) is rotatably connected with the opening and closing driving motor (121), the top wheel disc (127) is fixedly connected with the bottom end of the top material storage barrel (110), and the second slideway (128) is arranged on the top wheel disc (127) in a surrounding manner, the opening and closing piece (125) is arranged below the top wheel disc (127), the first slideway (126) is arranged on the opening and closing piece (125), the bottom wheel disc (123) is arranged below the opening and closing sheet (125), the gear teeth (124) are arranged on the bottom wheel disc (123), the gear teeth (124) are meshed with the opening and closing driving gear (122), the bottom end of the connecting shaft (1210) is rotatably connected with the bottom wheel disc (123), the top end of the connecting shaft (1210) is fixedly connected with the hanging connecting piece (129), the connecting shaft (1210) penetrates through the opening and closing sheet (125) and the second slideway (128), the connecting shaft (1210) is rotationally connected with the opening and closing sheet (125), the fixed shaft (1211) is arranged on the bottom wall of the top wheel disc (127) in a surrounding way, the fixed shaft (1211) penetrates through the first slideway (126), and the bottom end of the fixed shaft (1211) is not in contact with the bottom wheel disc (123).

4. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 3, characterized in that: support device (21) are including supporting base (210), mounting panel one (211) and mounting panel two (212), on supporting base (210) was located to mounting panel one (211) and mounting panel two (212), mounting panel one (211) is symmetrical arrangement with mounting panel two (212), the bottom and the support base (210) of storage vat support arm (111) keep fixed connection, between storage vat support arm (111) of both sides were located to mounting panel one (211) and mounting panel two (212).

5. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 4, which is characterized in that: the driving device (22) comprises a film supply motor (220), a traction roller (221), a film storage roller (222), a first tensioning roller (223) and a second tensioning roller (224), the film supply motor (220) is arranged on the first mounting plate (211), one end of the traction roller (221) is rotatably connected with the film supply motor (220), two ends of the traction roller (221) are respectively and rotatably connected with the first mounting plate (211) and the second mounting plate (212), the film storage roller (222) is arranged right below the traction roller (221), the first tensioning roller (223) is arranged right in front of the traction roller (221), the second tensioning roller (224) is arranged in front of the first tensioning roller (223), the height of the second tensioning roller (224) is lower than that of the first tensioning roller (223), and the two ends of the film storage roller (222), the first tensioning roller (223) and the second tensioning roller (224) are respectively and rotatably connected with the first mounting plate (211) and the second mounting plate (212).

6. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 5, which is characterized in that: the rotary stepping type traction device (31) comprises a first fixed sleeve plate (310), a connecting column (311), a second fixed sleeve plate (312), a former (313), an L-shaped connecting arm (314), a traction driving motor (315), a limiting shaft (316), a rotating shaft (317), a rotating disc (318), a limiting plate (319), a sliding chute (3110), a C-shaped contact ring (3111), a memory alloy bump (3112) and a sleeve embedding disc (3113), wherein the first fixed sleeve plate (310) is sleeved on a Z-shaped discharging pipe (1212), the first fixed sleeve plate (310) is fixedly connected with the Z-shaped discharging pipe (1212), the second fixed sleeve plate (312) is arranged below the first fixed sleeve plate (310), the first fixed sleeve plate (310) is connected with the second fixed sleeve plate (312) through the connecting column (311), the former (313) is fixedly connected with the second fixed sleeve plate (312), a gap is reserved between the second fixed sleeve plate (312) and the former (313) and the Z-shaped blanking pipe (1212), the L-shaped connecting arm (314) is arranged on the storage barrel supporting arm (111), the traction driving motor (315) is arranged on the L-shaped connecting arm (314), the rotating shaft (317) and the traction driving motor (315) are rotatably connected, the limiting shaft (316) is fixedly connected on the L-shaped connecting arm (314), the rotating disc (318) is fixedly connected on the rotating shaft (317), the rotating disc (318) is sleeved and embedded in the sleeve embedding disc (3113), the sleeve embedding disc (3113) and the rotating disc (318) are rotatably connected, the limiting plate (319) is fixedly connected on the sleeve embedding disc (3113), the chute (0) is arranged at one end of the limiting plate (319), the limiting shaft (316) penetrates through the chute (3110), the C-shaped contact ring (3111) is fixedly connected on the sleeve embedding disc (3113), the memory alloy salient points (3112) are arranged on the peripheral curved surface of the C-shaped contact ring (3111) in a surrounding mode.

7. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 6, which is characterized in that: the wind pressure contact type longitudinal film sealing device (32) comprises triangular connecting plates (3214) (320), a supporting transverse plate (321), a supporting vertical plate (322), a wind storage bin (323), a collision fan (324), an air pipe (325), a longitudinal sealing driving motor (326), a transmission shaft (327), a transmission wheel (328), a transmission belt (329), a first driving gear (3210), a second driving gear (3211), a rack plate (3212), a longitudinal sealing strip (3213), a connecting plate (3214), a guide rod (3215), a support rod (3216) and a guide lantern ring (3217), wherein the triangular connecting plates (3214) (320) are arranged on a support arm (111) of the storage barrel, two ends of the supporting transverse plate (321) are respectively connected with the triangular connecting plates (3214) (320) on two sides, the supporting vertical plate (322) is arranged on the supporting transverse plate (321), the wind storage bin (323) is arranged on the supporting transverse plate (321), the collision fan (324) is arranged on the top wall of the air storage bin (323), the air pipe (325) is arranged on the side wall of the air storage bin (323), the internal space of the air storage bin (323) is communicated with the air pipe (325), the longitudinal sealing driving motors (326) are arranged on the bottom wall of the supporting transverse plate (321), the transmission shafts (327) are rotatably connected on the supporting transverse plate (321), two groups of transmission shafts (327) are arranged, the longitudinal sealing driving motors (326) are rotatably connected with the transmission shaft (327) on one side, the transmission wheel (328) is arranged on the transmission shaft (327), the transmission belt (329) is sleeved on the transmission wheel (328), the first driving gear (3210) is arranged on the transmission shaft (327) connected with the longitudinal sealing driving motors (326), the second driving gear (3211) is arranged on the transmission shaft (327) on the other side, the rack plate (3212) is arranged between the first driving gear (3210) and the second driving gear (3211), the rack plates (3212) are respectively engaged with the first driving gear (3210) and the second driving gear (3211), the rack plates (3212) are provided with two sets, the first driving gear (3210) and the second driving gear (3211) are half gears, both ends of the rack plates (3212) are respectively connected with the connecting plate (3214) and the longitudinal seal (3213), the guide rods (3215) are distributed between the upper and lower rack plates (3212) at equal intervals, one end of each guide rod (3215) is connected with the longitudinal seal (3213), the other end of each guide rod (3215) is connected with the connecting plate (3214), the guide rods (3215) penetrate through the guide lantern rings (3217), the guide rods (3215) and the guide lantern rings (3217) are slidably connected, the support rods (6) are symmetrically arranged on both sides of the guide lantern rings (3217), and one end of each support rod (3216) is fixedly connected with the guide lantern rings (3217), the other end of the supporting rod (3216) is fixedly connected with the supporting vertical plate (322).

8. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 7, is characterized in that: the bidirectional opposite-punching type film sealing device (41) comprises a film sealing connecting arm (410), a U-shaped supporting plate (411), a mounting block (412), a sliding rod (413), a connecting cross rod I (414), a connecting cross rod II (415), a connecting cross rod III (416), a transverse sealing strip (417), a cutting blade (418), a transverse sealing driving motor (419), a transverse sealing gear (4110), a partition plate (4111), a driving disc (4112) and a swinging rod (4113), wherein one end of the film sealing connecting arm (410) is connected with the storage barrel supporting arm (111), the other end of the film sealing connecting arm (410) is connected with the side wall of the U-shaped supporting plate (411), the transverse sealing driving motor (419) is arranged on the bottom wall of the U-shaped supporting plate (411), the mounting block (412) is arranged on the side wall of the U-shaped supporting plate (411), the sliding rod (413) penetrates through the mounting block (412), and the sliding rod (413) is in sliding connection with the mounting block (412), one end of the sliding rod (413) is fixedly connected with the first connecting cross rod (414), the other end of the sliding rod (413) is fixedly connected with the second connecting cross rod (415), the third connecting cross rod (416) is arranged between the first connecting cross rod (414) and the second connecting cross rod (415), the third connecting cross rod (416) is connected with the sliding rod (413) in a sliding manner, the horizontal sealing gear (4110) is rotatably connected to the U-shaped supporting plate (411), the horizontal sealing gear (4110) is provided with two groups, the horizontal sealing driving motor (419) is rotatably connected with the horizontal sealing gear (4110) on one side, the clapboard (4111) is arranged on the horizontal sealing gear (4110), the driving disc (4112) is rotatably connected to the clapboard (4111), the driving disc (4112) is fixedly connected with the horizontal sealing gear (4110), one end of the swinging rod (4113) is rotatably connected to the driving disc (4112), the swing rod (4113) on the driving disc (4112) above the cross sealing driving motor (419) is rotatably connected with the connecting cross rod III (416), the swing rod (4113) on the other side is rotatably connected with the connecting cross rod I (414), the cross sealing strips (417) are symmetrically arranged and respectively arranged on the connecting cross rod II (415) and the connecting cross rod III (416), and the cutting blade (418) is arranged in a groove on the cross sealing strip (417).

9. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 8, characterized in that: the nonlinear fluid receiving buffer device (42) comprises an installation vertical plate (420), a shock absorber (421), a pressure bearing plate (422) and a nonlinear fluid pressure bearing bag (423), wherein the installation vertical plate (420) is arranged on the supporting base (210), the top end of the pressure bearing plate (422) is hinged to the installation vertical plate (420), the bottom end of the shock absorber (421) is hinged to the installation vertical plate (420), the top end of the shock absorber (421) is hinged to the pressure bearing plate (422), the nonlinear fluid pressure bearing bag (423) is arranged on the installation vertical plate (420), and the nonlinear fluid pressure bearing bag (423) is filled with nonlinear fluid.

10. The ion cleaning type wind pressure collision type silicon carbide micro powder finished product packaging machine according to claim 9, is characterized in that: the C-shaped contact rings (3111) are symmetrically arranged on two sides of the Z-shaped blanking pipe (1212).

Images