CN209922476U - Revolution and rotation spiral discharge system - Google Patents

Abstract

The utility model discloses a revolution and rotation spiral discharging system, which comprises a bin body for storing materials, a revolution mechanism, a rotation mechanism and a feeding structure, wherein the rotation shaft of the rotation mechanism extends vertically, the lower end of the rotation shaft is connected with the output end of a rotation motor, the upper end of the rotation mechanism is connected with a driving lever transmission shaft, and the driving lever transmission shaft and the rotation shaft are connected in 90 degrees, so that the reversing can be completed only by connecting the driving lever transmission shaft and the rotation shaft in 90 degrees and the dust can be discharged in parallel at the bottom of the bin body; compared with the conventional mode of needing multiple commutations, the structure is simpler, the use of parts is reduced, the manufacturing cost is greatly reduced, and the subsequent maintenance is facilitated; through the feeding mechanism who sets up, can pack the discharged dust through feeding mechanism's discharge gate, constitute Z shape row system through driving lever transmission shaft, rotatory tower, reposition of redundant personnel tower, conveying pipe in addition, ensure that row material is stable smooth and easy.

Description

Revolution and rotation spiral discharge system

Technical Field

The utility model belongs to the technical field of the dust storage device and specifically relates to indicate a public rotation and rotation spiral discharge system.

Background

In the prior art, in order to enable the interior of the bin body to be conveniently discharged, the dust storage device needs to be provided with a revolution mechanism, an autorotation mechanism and a material stirring rod, the material stirring rod is installed on the revolution mechanism, the revolution mechanism is used for driving the material stirring rod to rotate 360 degrees in the bin body, and the autorotation mechanism is connected with the material stirring rod through a transmission shaft connected with a motor so as to drive the material stirring rod to rotate to discharge the materials. However, in the prior art, a reversing speed reducer needs to be arranged between a motor and a transmission shaft to realize reversing, and the reversing between the transmission shaft and a material stirring rod needs to be realized through the matching of a worm or a chain and a chain wheel; the reversing mode causes complex structure, increases the manufacturing cost due to excessive parts, and is not beneficial to subsequent maintenance and repair.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main objective provides a public rotation spiral discharge system, and it can solve dust storage device's rotation mechanism in the past and the switching-over between the material pole of dialling has the problem that the structure is complicated, simultaneously, constitutes Z shape row system through driving lever transmission shaft, rotatory tower, reposition of redundant personnel tower, conveying pipe, ensures to arrange that the material is stable smooth and easy.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a revolution and rotation spiral discharge system comprises

The bin bottom of the bin body is arranged in a flat bottom structure, and the bottom of the bin body is provided with an opening;

the revolution mechanism comprises a revolution tower, a rotary support, a revolution motor and a diversion tower, wherein the revolution tower is arranged on the diversion tower through the rotary support, and the revolution motor is connected with the rotary support to drive the revolution tower to rotate at an opening of the bin body;

the self-rotation mechanism comprises a driving lever transmission shaft, a self-rotation motor and a driving lever, the driving lever transmission shaft is arranged on the rotating tower and rotates synchronously with the rotating tower, and the self-rotation motor is arranged on the shunting tower; the rotating shaft is arranged on the rotating tower and the flow dividing tower, the rotating shaft vertically extends, the lower end of the rotating shaft is connected with the output end of the rotating motor, the upper end of the rotating shaft is connected with the driving lever transmission shaft, and the driving lever transmission shaft and the rotating shaft are connected in a 90-degree manner; the deflector rod is arranged on the deflector rod transmission shaft, and the deflector rod is positioned in the bin body and is parallel to the bin bottom;

the feeding mechanism comprises a feeding pipe and a feeding rod, the feeding pipe is provided with a feeding hole and a discharging hole, and the feeding hole is arranged below the flow dividing tower; the feed rod is arranged in the feed pipe and is connected with a row of material motors.

As a preferred embodiment: the driving lever transmission shaft is provided with a first sector gear, one end of the rotation shaft is provided with a rotation seat provided with a second sector gear, and the first sector gear is meshed with the second sector gear.

As a preferred embodiment: and couplings are arranged between the output end of the rotation motor and the rotation shaft and between the rotation shaft and the rotation seat.

As a preferred embodiment: the head end of the deflector rod transmission shaft is provided with a first bearing assembly, the tail end of the deflector rod transmission shaft is provided with a second bearing assembly, and the deflector rod transmission shaft is fixedly arranged on the rotating tower through the first bearing assembly and the second bearing assembly.

As a preferred embodiment: one end of the driving lever transmission shaft is provided with a mounting convex part, the driving lever is provided with a mounting concave part, and the driving lever is matched with the mounting convex part through the mounting concave part and forms detachable mounting.

As a preferred embodiment: the rotary support comprises an inner support and an outer support which are meshed with each other, the splitter tower is fixed on the inner support, and the rotating tower is fixed on the outer support;

the output end of the revolution motor is provided with a transmission gear, and the outer support is provided with convex teeth meshed with the transmission gear.

As a preferred embodiment: and a rotary sealing element is arranged at the joint between the rotary tower and the opening.

As a preferred embodiment: and a decompression cone is arranged at the top of the rotating tower.

As a preferred embodiment: the driving lever and the feeding lever are arranged in a threaded rod structure and are provided with a lever body and spiral driving pieces formed on the peripheral side surface of the lever body.

As a preferred embodiment: one end of the deflector rod is concavely provided with an end groove towards the other end, and one end of the deflector rod is welded with a joint which comprises an extending section and a locking section; the mounting concave part is arranged on the joint and penetrates through and extends into the section and the locking section, the extending section is adapted to the end groove, the locking section is exposed out of the deflector rod, and the outer wall surface of the end groove and the outer wall surface of the locking section are welded and fixed;

the installation convex part is provided with a first connecting hole, the locking section is provided with a second connecting hole, and the first connecting hole and the corresponding second connecting hole are detachably fixed through screws.

Compared with the prior art, the utility model obvious advantage and beneficial effect have, particularly, can know by above-mentioned technical scheme: the rotation motor is arranged on the flow dividing tower, the rotation shaft vertically extends, the lower end of the rotation shaft is connected to the output end of the rotation motor, and the upper end of the rotation shaft is connected to the driving lever transmission shaft; therefore, the reversing can be completed only by connecting the driving rod transmission shaft with the rotating shaft at 90 degrees, and the dust is discharged in parallel to the bottom of the bin body; compared with the conventional mode of needing multiple commutations, the structure is simpler, the use of parts is reduced, the manufacturing cost is greatly reduced, and the subsequent maintenance is facilitated; and through the feeding mechanism who sets up, can pack discharged dust through feeding mechanism's discharge gate, compare in the mode that directly will fall outside the storehouse body in the past, can avoid dust secondary pollution all around environment, here, constitute Z shape row system through driving lever transmission shaft, rotating tower, reposition of redundant personnel tower, conveying pipe, ensure to arrange material stably smooth and easy.

In addition, the rotation shaft and the driving lever transmission shaft are connected through the first sector gear and the second sector gear, and compared with the structure that a worm needs to be connected or a chain wheel and a chain need to be connected in the past, the assembly is simpler and more convenient.

To illustrate the structural features and functions of the present invention more clearly, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of the present invention.

Fig. 2 is a schematic view of the rotation mechanism according to the preferred embodiment of the present invention.

Fig. 3 is a partially enlarged view of fig. 2A.

Fig. 4 is a partially exploded view of the transmission shaft and the shift lever of the preferred embodiment of the present invention.

Fig. 5 is a schematic view of the revolution mechanism according to the preferred embodiment of the present invention.

Fig. 6 is a partially enlarged view of fig. 5B.

Fig. 7 is a schematic view of a feeding mechanism according to a preferred embodiment of the present invention.

The attached drawings indicate the following:

10. cabin 20 and revolution mechanism

21. Rotating tower 212, rotating seal

211. Decompression cone 22, swivel support

221. Inner support 222 and outer support

2221. Convex tooth 23 and revolution motor

231. Transmission gear 24 and flow dividing tower

30. Rotation mechanism 31 and deflector rod transmission shaft

311. First sector gear 312, first bearing assembly

313. Second bearing Assembly 314, mounting lug

32. Rotation shaft 321 and second sector gear

33. Rotation motor 331 and coupling

34. Deflector rod 341, mounting recess

342. End groove 343, joint

3431. An extending section 3432 and a locking section

40. Feeding mechanism 41 and feeding pipe

411. Feed inlet 412, discharge outlet

42. A feed rod.

Detailed Description

Referring to fig. 1 to 7, a detailed structure of a preferred embodiment of the present invention is shown, which is a revolution and rotation spiral discharging system, comprising a bin 10, a revolution mechanism 20, a rotation mechanism 30 and a feeding mechanism 40.

The bin body is a storage bin body for storing dust, the bin bottom of the bin body 10 is in a flat bottom structure, and an opening is formed in the bottom of the bin body 10.

The revolution mechanism 20 comprises a revolution tower 21, a revolution support 22, a revolution motor 23 and a shunt tower 24, the revolution tower 21 is arranged on the shunt tower 24 through the revolution support 22, and the revolution motor 23 is connected with the revolution support 22 to drive the revolution tower 21 to rotate at the opening of the silo 10.

The rotation mechanism 30 comprises a driving lever transmission shaft 31, a rotation shaft 32, a rotation motor 33 and a driving lever 34, the driving lever transmission shaft 31 is installed on the rotating tower 21 and rotates synchronously with the rotating tower 21, and the rotation motor 33 is installed on the shunting tower 24; the rotation shaft 32 is arranged on the rotation tower 21 and the diversion tower 24, the rotation shaft 32 extends vertically, the lower end of the rotation shaft is connected with the output end of the rotation motor 33, the upper end of the rotation shaft is connected with the deflector rod transmission shaft 31, and the deflector rod transmission shaft 31 and the rotation shaft 32 are connected in a 90-degree manner; the shifting lever 34 is arranged on the shifting lever transmission shaft 31, and the shifting lever 34 is positioned in the bin body 10 and is parallel to the bin bottom.

In this embodiment, the lever transmission shaft 31 is installed with a first sector gear 311, and one end of the rotation shaft 32 is installed with a rotation seat having a second sector gear 321, and the first sector gear 311 is engaged with the second sector gear 321. And couplings 331 are provided between the output end of the rotation motor 33 and the rotation shaft 32 and between the rotation shaft 32 and the rotation base. The head end of the deflector shaft 31 is mounted with a first bearing assembly 312, the end is mounted with a second bearing assembly 313, and the deflector shaft 31 is fixedly mounted to the rotating tower 21 via the first bearing assembly 312 and the second bearing assembly 313.

The lever transmission shaft 31 has a mounting protrusion 314 at one end, the lever 34 has a mounting recess 341, and the lever 34 is detachably mounted by the mounting recess 341 fitting the mounting protrusion 314. Preferably, an end groove 342 is concavely formed at one end of the shift lever 34 toward the other end, a joint 343 is welded at one end of the shift lever 34, and the joint 343 includes an extending section 3431 and a locking section 3432; the mounting concave portion 341 is disposed on the joint 343, and penetrates and extends through the extending section 3431 and the locking section 3432, the extending section 3431 is fitted into the end groove 342, the locking section 3432 is exposed outside the shift lever 34, and the outer wall surface of the end groove 342 and the outer wall surface of the locking section 3432 are welded and fixed; moreover, the mounting protrusion 314 is provided with a first connecting hole, the locking section 3432 is provided with a second connecting hole, and the first connecting hole and the corresponding second connecting hole are detachably fixed by screws. With this structure, it is possible to facilitate the installation between the shift lever 34 and the shift lever transmission shaft 31.

The slewing bearing 22 comprises an inner bearing 221 and an outer bearing 222 which are meshed with each other, the splitter tower 24 is fixed on the inner bearing 221, and the rotating tower 21 is fixed on the outer bearing 222; specifically, the output end of the revolving motor 23 is provided with a transmission gear 231, and the outer support 222 is provided with a protruding tooth 2221 engaged with the transmission gear 231.

The feeding mechanism 40 comprises a feeding pipe 41 and a feeding rod 42, the feeding pipe 41 is provided with a feeding hole 411 and a discharging hole 412, and the feeding hole 411 is arranged below the flow dividing tower 24; the feeding rod 42 is arranged in the feeding pipe 41, and the feeding rod 42 is connected with a discharging motor 421. In this embodiment, the shift lever 34 and the feeding lever 42 are provided in a threaded rod structure, and have a rod body and a spiral shift piece formed on the peripheral side surface of the rod body.

In addition, the seam between the openings of the rotating tower 21 and the bin body 10 is provided with a rotating sealing element 212, and the rotating sealing element 212 can ensure that the dust in the bin body 10 can not fall out through the seam, thereby avoiding the secondary pollution caused by the dust to the surrounding environment of the bin body. A decompression cone 211 is installed at the top of the rotating tower 21.

The utility model discloses a design focus lies in: by installing the rotation motor 33 on the diversion tower 24, the rotation shaft 32 extends vertically and has a lower end connected to the output end of the rotation motor 33 and an upper end connected to the shift lever transmission shaft 31; therefore, the direction can be changed only by connecting the driving lever transmission shaft 31 and the rotating shaft 32 in an angle of 90 degrees, and the dust can be discharged in parallel to the bottom of the bin body 10; compared with the conventional mode of needing multiple commutations, the structure is simpler, the use of parts is reduced, the manufacturing cost is greatly reduced, and the subsequent maintenance is facilitated; and, through the feeding mechanism 40 that sets up, can pack the discharged dust through the discharge gate 42 of feeding mechanism 40, compare in the past and directly will fall the mode outside storehouse body 10, can avoid dust secondary pollution all around environment, here, through driving lever transmission shaft 31, rotatory tower 21, reposition of redundant personnel tower 24, feeding mechanism 40 formation Z shape row system, ensure that row material is stable smooth and easy.

In addition, the rotation shaft 32 and the driving lever transmission shaft 31 are connected through the first sector gear 311 and the second sector gear 321, and compared with the prior structure that worm connection or chain wheel and chain connection is needed, the assembly is simpler and more convenient.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (10)

1. The utility model provides a revolution and rotation spiral discharge system which characterized in that: comprises that

The bin body (10) is used for storing materials, the bin bottom of the bin body (10) is arranged in a flat-bottom structure, and the bottom of the bin body (10) is provided with an opening;

the revolution mechanism (20) comprises a revolution tower (21), a rotary support (22), a revolution motor (23) and a shunt tower (24), the revolution tower (21) is arranged on the shunt tower (24) through the rotary support (22), and the revolution motor (23) is connected with the rotary support (22) to drive the revolution tower (21) to rotate in an opening of the bin body (10);

the rotation mechanism (30) comprises a driving lever transmission shaft (31), a rotation shaft (32), a rotation motor (33) and a driving lever (34), the driving lever transmission shaft (31) is arranged on the rotating tower (21) and rotates synchronously with the rotating tower (21), and the rotation motor (33) is arranged on the shunting tower (24); the rotating shaft (32) is arranged on the rotating tower (21) and the flow dividing tower (24), the rotating shaft (32) extends vertically, the lower end of the rotating shaft is connected with the output end of the rotating motor (33), the upper end of the rotating shaft is connected with the driving lever transmission shaft (31), and the driving lever transmission shaft (31) is connected with the rotating shaft (32) in a 90-degree manner; the shifting rod (34) is arranged on the shifting rod transmission shaft (31), and the shifting rod (34) is positioned in the bin body (10) and is parallel to the bin bottom;

the feeding mechanism (40) comprises a feeding pipe (41) and a feeding rod (42), the feeding pipe (41) is provided with a feeding hole (411) and a discharging hole (412), and the feeding hole (411) is arranged below the flow dividing tower (24); the feeding rod (42) is arranged in the feeding pipe (41), and the feeding rod (42) is connected with a row of feeding motors (421).

2. The revolution-rotation spiral discharge system of claim 1, wherein: the driving lever transmission shaft (31) is provided with a first sector gear (311), one end of the rotation shaft (32) is provided with a rotation seat provided with a second sector gear (321), and the first sector gear (311) is meshed with the second sector gear (321).

3. The revolution-rotation spiral discharge system of claim 2, wherein: and couplings (331) are arranged between the output end of the rotation motor (33) and the rotation shaft (32) and between the rotation shaft (32) and the rotation seat.

4. The revolution-rotation spiral discharge system of claim 1, wherein: the head end of the deflector rod transmission shaft (31) is provided with a first bearing assembly (312), the tail end of the deflector rod transmission shaft is provided with a second bearing assembly (313), and the deflector rod transmission shaft (31) is fixedly arranged on the rotating tower (21) through the first bearing assembly (312) and the second bearing assembly (313).

5. The revolution-rotation spiral discharge system of claim 1, wherein: one end of the deflector rod transmission shaft (31) is provided with a mounting convex part (314), the deflector rod (34) is provided with a mounting concave part (341), and the deflector rod (34) is matched with the mounting convex part (314) through the mounting concave part (341) and can be detachably mounted.

6. The revolution-rotation spiral discharge system of claim 1, wherein: the rotary support (22) comprises an inner support (221) and an outer support (222) which are meshed with each other, the splitter tower (24) is fixed on the inner support (221), and the rotary tower (21) is fixed on the outer support (222);

the output end of the revolution motor (23) is provided with a transmission gear (231), and the outer support (222) is provided with a convex tooth (2221) meshed with the transmission gear (231).

7. The revolution-rotation spiral discharge system of claim 1, wherein: and a rotary sealing piece (212) is arranged at the joint between the rotary tower (21) and the opening.

8. The revolution-rotation spiral discharge system of claim 1, wherein: the top of the rotating tower (21) is provided with a decompression cone (211).

9. The revolution-rotation spiral discharge system of claim 1, wherein: the shifting rod (34) and the feeding rod (42) are arranged in a threaded rod structure and are provided with a rod body and spiral shifting pieces formed on the peripheral side surface of the rod body.

10. The revolution-rotation spiral discharge system of claim 5, wherein: an end groove (342) is concavely arranged at one end of the shifting lever (34) towards the other end, a joint (343) is welded at one end of the shifting lever (34), and the joint (343) comprises an extending section (3431) and a locking section (3432); the mounting concave part (341) is arranged on the connector (343), penetrates through the extending section (3431) and the locking section (3432), the extending section (3431) is adapted in the end groove (342), the locking section (3432) is exposed out of the shift lever (34), and the outer wall surface of the end groove (342) and the outer wall surface of the locking section (3432) are welded and fixed;

the installation convex part (314) is provided with a first connecting hole, the locking section (3432) is provided with a second connecting hole, and the first connecting hole and the corresponding second connecting hole are detachably fixed through screws.

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