CN214398534U - Vibration dish for cylindricality working of plastics - Google Patents

Abstract

The utility model relates to a cylindricality vibration dish for working of plastics belongs to the feeder equipment field, the on-line screen storage device comprises a base, the base top is provided with the cross-section and is the circular shape storage bucket, the inboard fixedly connected with of storage bucket is the spiral helicine cell body that rises, the base top is provided with the vibration subassembly that makes the storage bucket vibration, the storage bucket corresponds the cell body port position fixedly connected with branch flitch that rises, divide the flitch to keep away from a plurality of curved first transportation tracks that are of storage bucket position fixedly connected with, all first transportation tracks are kept away from and are divided two of equal fixedly connected with of flitch one end and transfer to the layer board, two of connection on the same first transportation track are transferred to the layer board and are a set of, two of every group are transferred to the layer board and are provided with to the flange and transfer to the groove. The present application has the effect of causing the vibratory pan to convey the worm in a uniform orientation that is in accordance with regulations.

Description

Vibration dish for cylindricality working of plastics

Technical Field

The application relates to the field of feeding equipment, in particular to a vibration disc for cylindrical plastic parts.

Background

The vibration disc is an auxiliary feeding device of an automatic assembling or automatic processing machine at present, and is widely applied to industries such as light industry machinery, electronic appliances and the like. The pulse electromagnet is arranged below the vibrating plate charging basket, so that the charging basket can vibrate in the vertical direction, and the inclined spring piece drives the charging basket to do torsional vibration around the vertical axis of the charging basket. The parts in the bucket, as a result of being subjected to such vibrations, rise along the helical track.

Referring to fig. 1, there is a worm 9 for being mounted on a motor spindle, the worm 9 includes a cylinder 91 sleeved on the motor spindle, a helical tooth 92 is fixedly connected to the surface of the cylinder 91, an annular flange 93 is fixedly connected to one end of the cylinder 91 close to a motor housing, and the diameter of the annular flange 93 is smaller than that of the cylinder 91. The annular flange 93 at one end of the worm 9 is required to be positioned at a position where the motor spindle is close to the motor shell during automatic assembly, so that the distance between the worm 9 and the motor shell is controlled by the annular flange 93, and the probability of friction between the spiral teeth 92 of the worm 9 and the motor shell is reduced.

In view of the above-mentioned related technologies, the inventor believes that the common vibration plate cannot accurately screen and adjust the orientation of the annular flange when feeding the worm screw, so that part of the worm screw reversely enters the assembly position and is manually rejected.

SUMMERY OF THE UTILITY MODEL

In order to enable the vibrating disk to convey the worm in a uniform direction, the application provides a vibrating disk for cylindrical plastic parts.

The application provides a cylindricality vibration dish for working of plastics adopts following technical scheme:

a vibration disc for cylindrical plastic parts comprises a base, a charging basket with a circular section is arranged above the base, a spiral ascending groove body is fixedly connected to the inner side of the charging basket, a vibration component for vibrating the charging basket is arranged above the base, a material distribution plate is fixedly connected to the position of the charging basket corresponding to the port of the ascending groove body, a plurality of arc first transportation tracks are fixedly connected to the position of the material distribution plate away from the charging basket, two direction-adjusting support plates are fixedly connected to one ends of all the first transportation tracks away from the material distribution plate, two direction-adjusting support plates connected to the same first transportation tracks are in a group, the two direction-adjusting support plates of each group are arranged in parallel, all the direction-adjusting support plates incline downwards from one end away from the charging basket to one end close to the charging basket, a gap left between the two direction-adjusting support plates of each group is equal to the diameter of a worm, and a direction-adjusting flange is fixedly connected to one end of each group of the two direction-adjusting support plates away from the charging basket, two of every group are transferred to equal fixed connection in two and are transferred to the layer board and be close to one side each other, and two of every group are transferred to the cylinder diameter that clearance between the flange is greater than the worm and is less than the worm diameter, and all transfer to the flange and are close to first transportation track one end and all seted up and transfer to the groove.

By adopting the scheme, when the annular flange of the worm faces the direction opposite to the conveying direction of the worm, the gravity center position of the worm moves to the direction-adjusting groove position, the worm starts to turn downwards from one end far away from the annular flange under the action of gravity, but the diameter of the worm is larger than the gap between the two direction-adjusting flanges, one end of the worm far away from the annular flange cannot turn downwards, the worm continues to move forwards along the direction-adjusting flange, when the annular flange moves to the direction-adjusting groove position, the worm starts to turn downwards from the annular flange under the action of gravity, and the worm falls onto the direction-adjusting supporting plate in a state that the annular flange faces downwards. Therefore, no matter the annular flange is the same or opposite to the conveying direction, the worm is adjusted to be in a state that the annular flange faces downwards by the direction adjusting flange and the direction adjusting groove after passing through the direction adjusting supporting plate, and the vibrating plate can convey the worm in a uniform direction meeting the specification.

Preferably, the vibration subassembly includes that fixed connection is close to base one side pulse electromagnet in the storage bucket, and the base corresponds a plurality of spring leafs of storage bucket position fixedly connected with department, and all spring leafs set up along the circumferencial direction array of storage bucket, and all spring leafs are the slope setting, and base one end fixed connection is kept away from to the spring leaf is close to base position department in the storage bucket.

By adopting the above scheme, pulse electromagnet is through pulse signal excitation regular vibration of self in vertical direction, and pulse electromagnet drives the storage bucket and is the vibration of vertical direction, and the spring leaf of slope drives the storage bucket and does the torsional pendulum vibration around its vertical axis, and then makes the worm in the storage bucket rise gradually along with the vibration in rising the cell body.

Preferably, the material distributing plate inclines downwards from one end close to the charging bucket to one end far away from the charging bucket, one side of the material distributing plate far away from the base is fixedly connected with a plurality of arc-shaped material distributing flanges, and the material distributing flanges are arranged along the circumferential direction of the charging bucket.

By adopting the scheme, the worm enters the position of the material distribution plate after being transported by the ascending groove body, the worm gradually slides downwards along the inclined direction of the material distribution plate, the sliding worm is intercepted in sequence by the material distribution flanges arranged on the material distribution plate, the worm is conveyed in a plurality of tracks at the position of the material distribution plate, and the conveying efficiency of the vibration plate is improved.

Preferably, the width of the first transportation track is equal to the diameter of the worm, all the first transportation tracks are arranged along the circumferential direction of the charging basket, one end of the first transportation track, which is close to the distributing plate, is fixedly connected to the position, corresponding to the distributing flange, of the distributing plate, a receiving disc is fixedly connected to the outer side of the charging basket, the receiving disc is located below the distributing plate and the first transportation track, and the receiving disc is spirally and downwardly arranged from one end, which is far away from the bottom plate, to one end, which is close to the bottom plate.

Through adopting above-mentioned scheme, under the effect of vibration, the worm on the branch charging tray moves to first transportation track along dividing the material flange, and when the worm axis direction is the same with first transportation track tangential direction, the worm enters into first transportation track, and the axis direction is different with first transportation track tangential line from dividing the charging tray tip and dropping on the take-up reel, the worm that accords with the requirement continues to transport forward.

Preferably, a second through groove is formed in the position, corresponding to the material receiving disc, of the material barrel.

By adopting the above scheme, the worm that drops in the transportation is retrieved to the take-up pan, and the worm that drops gets back to the storage bucket in through the second groove that the storage bucket corresponds take-up pan position department, through the transportation back of parts such as rising cell body and first transportation track, gets into the equipment position again.

Preferably, each group of direction-adjusting supporting plates are fixedly connected with arc-shaped second conveying rails at the ends far away from the first conveying rails, all the second conveying rails are arranged along the circumferential direction of the charging bucket, and the second conveying rails twist the worm from the downward state of the annular flange to the upward state of the annular flange in the conveying process.

By adopting the scheme, the worm adjusted into the state that the annular flange faces downwards by the direction adjusting supporting plate and the like is twisted to the state that the annular flange faces upwards by the second conveying track, and then the worm enters the subsequent assembly step in the state that the annular flange faces upwards, so that the assembly accuracy of the worm is improved.

Preferably, the first through grooves are formed in positions, far away from the first transportation rail, of all the second transportation rails, and the first through grooves are arranged along the length direction of the second transportation rails.

By adopting the scheme, when the worm is gradually twisted in the transportation process of the second transportation track, the situation that the worm is transversely arranged on the second transportation track can occur due to the sliding of the worm, and the transverse worm leaks out of the receiving disc from the first through groove arranged along the length direction of the second transportation track.

Preferably, the material receiving disc is far away from first transportation track one end position department fixedly connected with air nozzle corresponding to second transportation track, and the jet-propelled direction of air nozzle is the same with the direction that the worm was transported.

Through adopting above-mentioned scheme, the air nozzle accelerates the transport speed of the terminal worm of second transportation track through the air current of blowout and second transportation track transportation worm direction unanimity, reduces the worm and piles up the probability of jam at second transportation track terminal.

In conclusion, the invention has the following beneficial effects:

1. no matter the annular flange is the same or opposite to the conveying direction, the worm is adjusted to be in a state that the annular flange faces downwards by the direction adjusting flange and the direction adjusting groove after passing through the direction adjusting supporting plate, so that the worm can be conveyed by the vibrating plate according to a uniform direction meeting the specification;

2. the receiving disc recovers the worms falling off in the transportation process, the falling worms return to the charging barrel through a second through groove at the position of the charging barrel corresponding to the receiving disc, and enter the assembly position again after being transported by parts such as a lifting groove body, a first transportation rail and the like;

3. the air nozzle accelerates the conveying speed of the worm at the tail end of the second conveying track by ejecting the airflow in the direction consistent with the direction of the conveying worm of the second conveying track, and reduces the probability of the accumulation and blockage of the worm at the tail end of the second conveying track.

Drawings

FIG. 1 is a schematic view of a prior art worm;

FIG. 2 is a schematic structural view of a cylindrical vibratory plate for plastic articles according to an embodiment of the present disclosure;

FIG. 3 is a cross-sectional view of a cylindrical vibratory pan for plastic articles according to an embodiment of the present application;

FIG. 4 is a schematic structural view of a protruding second through slot of a vibration plate for cylindrical plastic parts according to an embodiment of the present disclosure;

fig. 5 is an enlarged view of part a of the embodiment of the present application.

Description of reference numerals: 1. a base; 2. a charging bucket; 21. a lifting groove body; 22. a second through groove; 3. a vibrating assembly; 31. a pulse electromagnet; 32. a spring plate; 4. a material distributing plate; 41. a material distributing flange; 5. a first transport track; 6. a take-up pan; 61. an air nozzle; 7. adjusting the direction of the supporting plate; 71. adjusting the direction of the flange; 72. a direction regulating groove; 8. a second transport track; 81. a first through groove; 9. a worm; 91. a cylinder; 92. helical teeth; 93. an annular flange.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses vibration dish for cylindricality working of plastics. Referring to fig. 2 and 3, including base 1, base 1 top is provided with the cross-section and is circular shape storage bucket 2, 2 inboard fixedly connected with of storage bucket is spiral helicine cell body 21 that rises, base 1 top is provided with vibration subassembly 3, vibration subassembly 3 includes that fixed connection is close to 1 one side pulse electromagnet 31 of base in storage bucket 2, base 1 corresponds a plurality of spring leaf 32 of 2 position departments fixedly connected with of storage bucket, all spring leaf 32 set up along the circumferencial direction array of storage bucket 2, all spring leaf 32 are the slope setting, base 1 one end fixed connection is kept away from in storage bucket 2 and is close to 1 position department of base in spring leaf 32. The pulse electromagnet 31 excites the pulse electromagnet to vibrate regularly in the vertical direction through pulse signals, the pulse electromagnet 31 drives the charging bucket 2 to vibrate in the vertical direction, the inclined spring piece 32 drives the charging bucket 2 to do torsional vibration around the vertical axis of the charging bucket, and then the worm 9 in the charging bucket 2 gradually rises along with the vibration in the rising groove body 21.

Referring to fig. 2 and 3, a material distributing plate 4 is fixedly connected to a position of the material barrel 2 corresponding to the port of the ascending groove body 21, the material distributing plate 4 is inclined downwards from one end close to the material barrel 2 to one end far away from the material barrel 2, one side of the material distributing plate 4 far away from the base 1 is fixedly connected with a plurality of arc-shaped material distributing flanges 41, and the material distributing flanges 41 are arranged along the circumferential direction of the material barrel 2. The worm 9 enters the position of the material distribution plate 4 after being transported by the ascending groove body 21, the worm 9 gradually slides downwards along the inclined direction of the material distribution plate 4, and the sliding worm 9 is intercepted in sequence by the material distribution flanges 41 arranged on the material distribution plate 4, so that the worm 9 is transported in a plurality of tracks at the position of the material distribution plate, and the conveying efficiency of the vibration plate is improved.

Referring to fig. 3 and 4, a plurality of curved first transportation tracks 5 of fixedly connected with of storage bucket 2, the width of first transportation track 5 equals the diameter of worm 9, all first transportation tracks 5 set up along the circumferencial direction of storage bucket 2, first transportation track 5 is close to branch flitch 4 one end fixed connection and divides flitch 4 to correspond branch material flange 41 position department, 2 outside fixedly connected with take-up (stock) pans 6 of storage bucket, take-up (stock) pans 6 are located branch flitch 4 and first transportation track 5 below, take-up (stock) pans 6 is by keeping away from bottom plate one end to being close to bottom plate one end spiral and setting down. The position of the charging basket 2 corresponding to the receiving tray 6 is provided with a second through groove 22. Under the action of vibration, the worm 9 on the distributing disc moves towards the first conveying track 5 along the distributing flange 41, when the axial direction of the worm 9 is the same as the tangential direction of the first conveying track 5, the worm 9 enters the first conveying track 5, the axial direction is different from the tangential direction of the first conveying track 5, the worm 9 which meets the requirement continuously conveys forwards and falls onto the receiving disc 6 from the end part of the distributing disc. The worm 9 that drops in the transportation is retrieved to take-up (stock) pan 6, and the worm 9 that drops gets back to in the storage bucket 2 through the second logical groove 22 that storage bucket 2 corresponds take-up (stock) pan 6 position department, through the transportation back of parts such as ascending cell body 21 and first transportation track 5, gets into the equipment position again.

Referring to fig. 3 and 5, one end of each first transportation track 5, which is far away from the material distribution plate 4, is fixedly connected with two direction-adjusting supporting plates 7, the two direction-adjusting supporting plates 7 connected to the same first transportation track 5 are in a group, the two direction-adjusting supporting plates 7 of each group are arranged in parallel, all the direction-adjusting supporting plates 7 are downwards inclined from one end, which is far away from the material barrel 2, to the end, which is close to the material barrel 2, of the material barrel, and a gap reserved between the two direction-adjusting supporting plates 7 of each group is equal to the diameter of the worm 9. Two of every group transfer to layer board 7 and keep away from equal fixedly connected with of storage bucket 2 one end and transfer to flange 71, two of every group transfer to flange 71 all fixedly connected with two transfer to layer board 7 and be close to one side each other, two of every group transfer to the cylinder 91 diameter that clearance between flange 71 is greater than worm 9 and is less than worm 9 diameter, all transfer to flange 71 and be close to first transportation track 5 one end and all seted up and transfer to groove 72. The first transportation rail 5 transports the worm 9 to the position of the direction-adjusting pallet 7 along the tangential direction of the first transportation rail 5, when the annular flange 93 of the worm 9 is aligned with the transportation direction of the worm 9, the gravity center position of the worm 9 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from the position of the annular flange 93 under the action of gravity, the diameter of the annular flange 93 is smaller than the gap between the two direction-adjusting flanges 71, and the worm 9 falls onto the direction-adjusting pallet 7 in a state that the annular flange 93 faces downwards. When the annular flange 93 of the worm 9 faces the direction opposite to the conveying direction of the worm 9, after the gravity center position of the worm 9 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from one end far away from the annular flange 93 under the action of gravity, but the diameter of the worm 9 is larger than the gap between the two direction-adjusting flanges 71, one end of the worm 9 far away from the annular flange 93 cannot turn downwards, the worm 9 continues to move forwards along the direction-adjusting flange 71, when the annular flange 93 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from the annular flange 93 under the action of gravity, and the worm 9 falls onto the direction-adjusting supporting plate 7 in a state that the annular flange 93 faces downwards. Therefore, regardless of whether the annular flange 93 is in the same direction or in the opposite direction to the conveying direction, the worm 9 is adjusted to a state in which the annular flange 93 faces downward by the direction-adjusting flange 71 and the direction-adjusting groove 72 after passing through the direction-adjusting pallet 7, and the oscillating plate can convey the worm 9 in a uniform direction in accordance with the specification.

Referring to fig. 2 and 3, each group of direction-adjusting supporting plates 7 is fixedly connected with an arc-shaped second transportation rail 8 at one end far away from the first transportation rail 5, all the second transportation rails 8 are arranged along the circumferential direction of the charging bucket 2, and the second transportation rails 8 twist the worm 9 to the upward state of the annular flange 93 from the downward state of the annular flange 93 in the transportation process. The second transportation rail 8 twists the worm 9 adjusted to the downward state of the annular flange 93 by the direction-adjusting pallet 7 and the like to the upward state of the annular flange 93, and then the worm 9 enters the subsequent assembly step with the upward state of the annular flange 93, thereby improving the accuracy of the assembly of the worm 9.

Referring to fig. 2, a first through groove 81 is formed in a position where all the second transportation rails 8 are far away from the first transportation rail 5, and the first through groove 81 is formed in the length direction of the second transportation rails 8. When the worm 9 is gradually twisted by the second transportation rail 8 during transportation, the situation that the worm 9 is transversely arranged on the second transportation rail 8 may occur due to the sliding of the worm 9, and at the moment, the transversely arranged worm 9 leaks out to the material receiving tray 6 from the first through groove 81 arranged along the length direction of the second transportation rail 8.

Referring to fig. 2, an air nozzle 61 is fixedly connected to the position of the material receiving tray 6 corresponding to the second transportation rail 8, which is far away from the first transportation rail 5, and the air injection direction of the air nozzle 61 is the same as the transportation direction of the worm 9. The air nozzle 61 accelerates the transportation speed of the worm 9 at the tail end of the second transportation rail 8 by ejecting the air flow in the same direction as the transportation worm 9 of the second transportation rail 8, and reduces the probability of the worm 9 accumulating and blocking at the tail end of the second transportation rail 8.

The implementation principle of a cylindricality vibration dish for working of plastics of this application embodiment does: firstly, a worker pours the worm 9 into the charging basket 2, then the pulse electromagnet 31 excites the regular vibration of the charging basket in the vertical direction through a pulse signal, the pulse electromagnet 31 drives the charging basket 2 to vibrate in the vertical direction, the inclined spring piece 32 drives the charging basket 2 to do torsional vibration around the vertical axis, and then the worm 9 in the charging basket 2 gradually rises along with the vibration in the ascending groove body 21 and is finally conveyed to the powder tray.

Under the action of vibration, the worm 9 on the distributing disc moves towards the first conveying track 5 along the distributing flange 41, when the axial direction of the worm 9 is the same as the tangential direction of the first conveying track 5, the worm 9 enters the first conveying track 5, the axial direction is different from the tangential direction of the first conveying track 5, the worm 9 which meets the requirement continuously conveys forwards and falls onto the receiving disc 6 from the end part of the distributing disc.

The first transportation rail 5 transports the worm 9 to the position of the direction-adjusting pallet 7 along the tangential direction of the first transportation rail 5, when the annular flange 93 of the worm 9 is aligned with the transportation direction of the worm 9, the gravity center position of the worm 9 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from the position of the annular flange 93 under the action of gravity, the diameter of the annular flange 93 is smaller than the gap between the two direction-adjusting flanges 71, and the worm 9 falls onto the direction-adjusting pallet 7 in a state that the annular flange 93 faces downwards. When the annular flange 93 of the worm 9 faces the direction opposite to the conveying direction of the worm 9, after the gravity center position of the worm 9 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from one end far away from the annular flange 93 under the action of gravity, but the diameter of the worm 9 is larger than the gap between the two direction-adjusting flanges 71, one end of the worm 9 far away from the annular flange 93 cannot turn downwards, the worm 9 continues to move forwards along the direction-adjusting flange 71, when the annular flange 93 is moved to the position of the direction-adjusting groove 72, the worm 9 starts to turn downwards from the annular flange 93 under the action of gravity, and the worm 9 falls onto the direction-adjusting supporting plate 7 in a state that the annular flange 93 faces downwards. Therefore, regardless of whether the annular flange 93 is in the same direction or in the opposite direction to the conveying direction, the worm 9 is adjusted to a state in which the annular flange 93 faces downward by the direction-adjusting flange 71 and the direction-adjusting groove 72 after passing through the direction-adjusting pallet 7, and the oscillating plate can convey the worm 9 in a uniform direction in accordance with the specification.

The second transportation rail 8 twists the worm 9 adjusted to the downward state of the annular flange 93 by the direction-adjusting pallet 7 and the like to the upward state of the annular flange 93, and then the worm 9 enters the subsequent assembly step with the upward state of the annular flange 93, thereby improving the accuracy of the assembly of the worm 9.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a cylindricality vibration dish for working of plastics, includes base (1), its characterized in that: a charging basket (2) with a circular section is arranged above a base (1), a spiral ascending groove body (21) is fixedly connected on the inner side of the charging basket (2), a vibration component (3) which can make the charging basket (2) vibrate is arranged above the base (1), a material distributing plate (4) is fixedly connected at the position of the port of the ascending groove body (21) corresponding to the charging basket (2), a plurality of first arc-shaped transportation rails (5) are fixedly connected at the position of the material distributing plate (4) far away from the charging basket (2), one end of each first transportation rail (5) far away from the material distributing plate (4) is fixedly connected with two direction-adjusting supporting plates (7), the two direction-adjusting supporting plates (7) connected on the same first transportation rail (5) form a group, the two direction-adjusting supporting plates (7) of each group are arranged in parallel, one end of each direction-adjusting supporting plate (7) far away from the charging basket (2) inclines downwards to the end close to the charging basket (2), two of every group transfer to the clearance that leaves between layer board (7) equal with worm (9) diameter, two of every group transfer to layer board (7) keep away from the equal fixedly connected with of storage bucket (2) one end and transfer to flange (71), two of every group transfer to equal fixed connection in flange (71) two transfer to layer board (7) and be close to one side each other, two of every group transfer to cylinder (91) diameter that clearance between flange (71) is greater than worm (9) and be less than worm (9) diameter, all transfer to flange (71) and be close to first transportation track (5) one end and have all seted up and transferred to groove (72).

2. The vibratory pan of claim 1, wherein: vibration subassembly (3) are close to base (1) one side pulse electromagnet (31) including fixed connection in storage bucket (2), and base (1) corresponds a plurality of spring leaf (32) of storage bucket (2) position department fixedly connected with, and all spring leaf (32) set up along the circumferencial direction array of storage bucket (2), and all spring leaf (32) are the slope setting, and base (1) one end fixed connection is kept away from in spring leaf (32) and base (1) position department is close to in storage bucket (2).

3. The vibratory pan of claim 1, wherein: divide flitch (4) to keeping away from storage bucket (2) one end downward sloping by being close to storage bucket (2) one end, divide flitch (4) to keep away from a plurality of curved branch material flanges (41) of base (1) one side fixedly connected with, divide material flange (41) to set up along storage bucket (2) circumferencial direction.

4. The vibratory pan of claim 1, wherein: the width of first transportation track (5) equals the diameter of worm (9), the circumferencial direction setting along storage bucket (2) is followed in all first transportation track (5), first transportation track (5) are close to branch flitch (4) one end fixed connection and correspond branch material flange (41) position department in branch flitch (4), storage bucket (2) outside fixedly connected with take-up (6), take-up (6) are located branch flitch (4) and first transportation track (5) below, take-up (6) are by keeping away from bottom plate one end to being close to bottom plate one end spiral and setting down.

5. The vibratory pan of claim 4, wherein: the position of the charging bucket (2) corresponding to the receiving disc (6) is provided with a second through groove (22).

6. The vibratory pan of claim 1, wherein: every group transfers to layer board (7) and keeps away from equal fixedly connected with curved second transportation track (8) of first transportation track (5) one end, and all second transportation tracks (8) set up along the circumferencial direction of storage bucket (2), and second transportation track (8) twist round worm (9) to annular flange (93) state up by annular flange (93) state down in the transportation.

7. The vibratory pan of claim 6, wherein: all second transportation track (8) are kept away from first transportation track (5) position department and have been seted up first logical groove (81), and first logical groove (81) set up along second transportation track (8) length direction.

8. The vibratory pan of claim 6, wherein: the material receiving disc (6) is fixedly connected with an air nozzle (61) corresponding to the position of one end, far away from the first transportation track (5), of the second transportation track (8), and the air injection direction of the air nozzle (61) is the same as the transported direction of the worm (9).

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