CN210912945U - Granule liquid filling machine - Google Patents

Abstract

The utility model belongs to the technical field of machinery, a granule liquid filling machine is related to. The utility model comprises a frame, a feed hopper is arranged on the frame, a cylindrical shell is arranged below the feed hopper, and a material scattering port is arranged on the lower side edge of the cylindrical shell; a baffle plate is arranged on the cylindrical shell; a material separating cylinder is arranged on the periphery of the cylindrical shell through a rotating shaft, and a plurality of blanking pipes are arranged at the bottom of the material separating cylinder; the frame is provided with a driving mechanism which can drive the rotating shaft to rotate; a rotating disc is arranged below the material separating cylinder through a rotating shaft, and a plurality of material collecting pipes are arranged on the rotating disc; the lower side surface of the rotating disc is provided with movable covers with the same number as the material collecting pipes through a pivot, and the frame is provided with an opening and closing mechanism which can drive one movable cover to automatically open and close the lower ports of the material collecting pipes when the rotating disc rotates; the frame is also provided with a lifting mechanism which can drive the rotating disc to ascend and descend on the rotating shaft. The utility model has the advantages that: effectively improve the work efficiency of granule liquid filling machine.

Description

Granule liquid filling machine

Technical Field

The utility model belongs to the technical field of machinery, a granule liquid filling machine is related to.

Background

The granule filling machine is suitable for small bag package in the aspects of medicine, food, chemical industry, pesticide and the like. Is suitable for manufacturers producing fine particles such as granular medicines, granulated sugar, coffee, fruit juice, tea, monosodium glutamate, salt, seeds, drying agents and the like. But traditional granule liquid filling machine can not keep up with such production speed, and degree of automation is also not high, need to drop into a large amount of manpower and materials, and not only the filling effect is not good, and is fast moreover, and the labour demand is many, and enterprise cost is higher, is unfavorable for large-scale production.

SUMMERY OF THE UTILITY MODEL

The utility model aims at having the above-mentioned problem to current technique, provided a granule liquid filling machine, the utility model aims to solve the technical problem that: how to improve the work efficiency of granule liquid filling machine.

The utility model discloses a following technical scheme realizes:

a pellet filling machine comprising a frame, and:

the feeding hopper is fixed on the frame;

a cylindrical housing fixed below the lower end of the feed hopper; a material scattering port is formed in the lower side edge of the cylindrical shell; the cylindrical shell is fixedly provided with a baffle;

the material separating barrel is arranged around the periphery of the cylindrical shell through a rotating shaft which is rotatably arranged on the rack; a plurality of blanking pipes communicated with the interior of the material distributing cylinder are uniformly arranged on the bottom of the material distributing cylinder around the cylindrical shell; the outer side edge of the baffle is arranged between the upper end opening of the blanking pipe and the inner wall of the material distributing cylinder; the rack is provided with a driving mechanism capable of driving the rotating shaft to rotate;

the rotating disc is coaxially arranged below the material distributing cylinder through a rotating shaft, and the rotating disc is provided with material collecting pipes the number of which is the same as that of the blanking pipes; the upper ports of the material collecting pipes respectively surround the periphery of the lower port of a blanking pipe, and the lower ports penetrate through the lower side surface of the rotating disc; the lower side surface of the rotating disc is provided with movable covers with the same number as the material collecting pipes through a pivot, and the movable covers are respectively positioned below the lower ports of one blanking pipe; the frame is provided with an opening and closing mechanism which can drive a movable cover to automatically open and close the lower port of the collecting pipe when the rotating disc rotates; the rack is also provided with a lifting mechanism which can drive the rotating disc to ascend and descend on the rotating shaft.

In the above granule filling machine, an arc-shaped plate is fixedly arranged on the cylindrical shell, and the arc-shaped plate is arranged between the upper end opening of the material collecting pipe and the inner wall of the material distributing cylinder.

In the granule filling machine, the lifting mechanism comprises a cylindrical supporting block, the supporting block is coaxially arranged and is slidably connected to the rotating shaft, and an annular groove is formed in the supporting block; a threaded rod is arranged on the rack, a rocking handle is fixedly arranged at the upper end of the threaded rod, and the lower end of the threaded rod is rotatably arranged on the rack; the threaded rod is in threaded connection with a threaded sleeve, and two sides of the threaded sleeve are respectively provided with a connecting rod; one end of each connecting rod extends to the periphery of the supporting block, and the other end of each connecting rod is fixedly connected with the threaded sleeve; the end part of the connecting rod extending to the periphery of the supporting block is fixedly provided with a pulley, the pulley extends into the annular groove, and the upper edge and the lower edge of the pulley are respectively contacted with the upper inner wall and the lower inner wall of the annular groove; a positioning column is arranged between the two connecting rods, the lower end of the positioning column is fixedly arranged on the rack, and the upper end of the positioning column is suspended; the positioning column is sleeved with a positioning sleeve, and the positioning sleeve is fixedly connected with the two connecting rods respectively.

In the above granule filling machine, a transparent cover is fixedly arranged on the cylindrical shell around the lower end of the feed hopper, and the outer side edge of the transparent cover extends to the periphery of the material separating barrel.

In the above granule filling machine, two auxiliary stay bars are provided around the periphery of the support block; the lower end of the auxiliary stay bar is fixed on the supporting block through a fixing plate, and the upper end of the auxiliary stay bar is provided with a threaded hole; threaded hole female connection has the regulation pole, adjust pole one end and stretch out the threaded hole outside and the tip supports and presses on the downside of rotary disk.

In the particle filling machine, a material shielding plate is slidably arranged on the edge of the material scattering port, and the size of the material shielding plate is larger than that of the material scattering port; the material covering plate is in threaded connection with a pull rod; the upper end of the pull rod extends out of the transparent cover.

In the above granule filling machine, the opening and closing mechanism includes a first fixing rod and a second fixing rod; the lower ends of the first fixed rod and the second fixed rod are uniformly arranged on a connecting rod, and the upper ends of the first fixed rod and the second fixed rod are both positioned between the lower side surface of the movable cover and the lower side surface of the rotating disc; the second fixing lever is located between the first fixing lever of the rotating disk and the supporting block and located at the rear side of the rotation of the first fixing lever.

Compared with the prior art, the device has the following advantages:

1. the particles to be filled are placed into the cylindrical shell through the feed hopper, and the particles directly fall on the bottom of the material separating cylinder. And then starting the driving mechanism, wherein the driving mechanism drives the rotating shaft to rotate, and the cylindrical shell is static relative to the material distributing cylinder at the moment because the feed hopper and the cylindrical shell are both fixed on the rack. The rotating shaft drives the rotating disc and the material distributing cylinder to rotate synchronously. The particles on the bottom of the material separating cylinder move to the periphery of the cylindrical shell from the inside of the cylindrical shell through the material spreading port under the action of centrifugal force. When particles on the periphery of the cylindrical shell pass through the baffle, the particles fall from the bottom of the material separating cylinder to the blanking pipe under the driving action of the baffle and are temporarily stored in the material collecting pipe below the blanking pipe under the centrifugal force. When the movable cover passes through the opening and closing mechanism, the opening and closing mechanism drives the movable cover to automatically open and close the lower port of the material collecting pipe, so that particles in the material collecting pipe fall into an external storage device. In this device, the granule is automatically moved to each collecting pipe through the rotation of a material separating cylinder, a baffle and a blanking pipe, so that the automatic filling function of the device is realized, and the working efficiency of the device is effectively improved. In addition, elevating system drive rotary disk rises and descends, changes the effective volume that forms between last side of rotary disk and the feed cylinder downside in order to adjust blanking pipe and the collection pipe to through the rotational speed of adjustment pivot, the granule quantity of further controlling the collection storage in the pipe, thereby make the quantity of the adjustable filling granule of this device, and accuracy when effectively improving this device filling granule.

2. The particles on the bottom of the material separating cylinder are collected between the arc-shaped plate and the cylindrical shell through the arc-shaped plate, the particles are prevented from moving to the edge of the material separating cylinder, meanwhile, the baffle is also favorable for driving the particles to fall into the blanking pipe, and the working efficiency of the baffle is effectively improved.

3. The pull rod is rotated to enable the covering plate to rise and fall under the driving of the pull rod, the distance between the lower side edge of the covering plate and the lower side edge of the material scattering port is changed, and therefore the quantity of the particles discharged from the material scattering port is adjusted, and the accuracy of the device during filling of the particles is further improved.

4. When the movable cover passes through the first fixed rod, the first fixed rod is in contact with the movable cover and enables the movable cover to rotate around the pivot shaft towards the supporting block, so that the lower port of the material collecting pipe above the movable cover is opened, and particles in the material collecting pipe fall into an external storage device. And as the rotating disc rotates, the second fixed rod is contacted with the end part of the movable cover and enables the movable cover to rotate outwards around the pivot, so that the lower port of the material collecting pipe above the movable cover is closed. The structure realizes that the movable cover automatically opens and closes the lower port of the collecting pipe, effectively improves the working efficiency of the device, and has simple structure and low cost.

Drawings

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

Fig. 2 is a sectional view of the structure at a-a in fig. 1.

Fig. 3 is a partially enlarged view at B in fig. 1.

Fig. 4 is a sectional view of the structure at B-B in fig. 2.

Fig. 5 is a partial enlarged view at D in fig. 1.

In the figure, 1, a frame; 11. a fixed mount; 2. a rotating shaft; 21. a motor; 3. a material separating barrel; 31. a blanking pipe; 4. a feed hopper; 41. a cover plate; 5. a cylindrical housing; 51. a material scattering port; 52. a baffle plate; 53. a transparent cover; 54. an arc-shaped plate; 55. a material covering plate; 551. a pull rod; 6. rotating the disc; 61. a material collecting pipe; 62. a movable cover; 621. a pivot; 622. a locking spring; 63. a first fixing lever; 64. a second fixing bar; 7. a support block; 71. a threaded rod; 72. a rocking handle; 73. a threaded sleeve; 74. a connecting rod; 741. an annular groove; 742. a pulley; 75. a positioning column; 76. a positioning sleeve; 77. a support block; 771. a threaded hole; 772. and adjusting the rod.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

Referring to fig. 1 to 5, a pellet filling machine comprises a frame 1, and:

the feed hopper 4 is fixed on the frame 1 through a fixing frame 11 vertically fixed on the frame 1; the upper end cover of the feed hopper 4 is covered with a cover plate 41;

a cylindrical shell 5 fixed below the lower port of the feed hopper 4 through a fixing frame 11; a material scattering port 51 is formed on the lower side edge of the cylindrical shell 5; a baffle plate 52 is fixedly arranged on the cylindrical shell 5;

the material separating barrel 3 is arranged around the periphery of the cylindrical shell 5 through a rotating shaft 2 which is rotatably arranged on the frame 1; a plurality of blanking pipes 31 communicated with the interior of the material distributing cylinder 3 are uniformly arranged on the bottom of the material distributing cylinder 3 around the cylindrical shell 5; the outer side edge of the baffle plate 52 is arranged between the upper end opening of the blanking pipe 31 and the inner wall of the material distributing cylinder 3; the frame 1 is provided with a driving mechanism capable of driving the rotating shaft 2 to rotate;

the rotating disc 6 is coaxially arranged below the material separating cylinder 3 through the rotating shaft 2, and the rotating disc 6 is provided with material collecting pipes 61 the same as the blanking pipes 31 in number; the upper ports of the material collecting pipes 61 respectively surround the periphery of the lower port of one blanking pipe 31, and the lower ports penetrate through the lower side surface of the rotating disc 6; the lower side surface of the rotating disc 6 is provided with movable covers 62 with the same number as the material collecting pipes 61 through a pivot 621, and the movable covers 62 are respectively positioned below the lower port of one blanking pipe 31; the frame 1 is provided with an opening and closing mechanism which can drive a movable cover 62 to automatically open and close the lower port of the material collecting pipe 61 when the rotating disc 6 rotates; the frame 1 is also provided with a lifting mechanism which can drive the rotating disc 6 to ascend and descend on the rotating shaft 2.

When the device works, particles to be filled are firstly placed into the cylindrical shell 5 through the feed hopper 4, and the particles directly drop on the bottom of the material separating barrel 3. And then the driving mechanism is started, the driving mechanism drives the rotating shaft 2 to rotate, and the feed hopper 4 and the cylindrical shell 5 are both fixed on the rack 1, so that the cylindrical shell 5 is static relative to the material separating barrel 3. The rotating shaft 2 drives the rotating disc 6 and the material separating cylinder 3 to synchronously rotate. The particles on the bottom of the dispensing cartridge 3 move under centrifugal force from the interior of the cylindrical housing 5 through the discharge opening 51 to the periphery of the cylindrical housing 5. When particles located on the periphery of the cylindrical housing 5 pass the baffle 52, the particles are subjected to centrifugal force and the baffle 52 to drive, fall from the bottom of the distribution cylinder 3 into the down pipe 31 and are temporarily stored in the collecting pipe 61 below the down pipe 31. When the movable cover 62 passes through the opening and closing mechanism, the opening and closing mechanism drives the movable cover 62 to automatically open and close the lower port of the material collecting pipe 61, so that the particles in the material collecting pipe 61 fall into an external storage device.

In the device, the particles are automatically moved to each collecting pipe 61 through the rotation of the material separating barrel 3 and the baffle plate 52 and the blanking pipe 31, so that the automatic filling function of the device is realized, and the working efficiency of the device is effectively improved.

In addition, the lifting mechanism drives the rotary disc 61 to ascend and descend, the distance between the upper side face of the rotary disc 6 and the lower side face of the material distributing cylinder 3 is changed to adjust the effective volume formed between the blanking pipe 31 and the material collecting pipe 61, and the quantity of particles stored in the material collecting pipe 61 is further controlled by adjusting the rotating speed of the rotating shaft 2, so that the device can adjust the quantity of filling particles, and the accuracy of the device in particle filling is effectively improved.

Preferably, the driving mechanism is a motor 21, and an output shaft of the motor 21 drives the rotating shaft 2 to rotate through gear transmission; the motor 21 is electrically connected to an external power source.

The motor 21 is used as a driving mechanism and is easy to obtain; the output shaft of the motor 21 drives the rotating shaft 21 to rotate, so that the material separating barrel 3 rotates, and the structure is simple and easy to install.

Further, a locking spring 622 is sleeved on the pivot 621; the lower end of the locking spring 622 is pressed against the boss at the lower end of the pivot 621, and the upper end of the locking spring 622 is pressed against the lower side surface of the movable cover 62; the upper side of the movable cover 62 is engaged against the lower side of the rotary disk 6 by the locking spring 622.

When the movable cover 62 closes the lower port of the collecting pipe 61, particles falling from the down pipe 31 are stored in the collecting pipe 61; when the movable cover 62 opens the lower end of the collecting pipe 61, the particles fall from the collecting pipe 61 to the outside storage device. The movable cover 62 is arranged to help the material collecting pipe 61 to store and realize the automatic particle filling function of the device.

Specifically, an arc-shaped plate 54 is fixedly arranged on the cylindrical shell 5, and the arc-shaped plate 54 is arranged between the upper end of the material collecting pipe 61 and the inner wall of the material distributing cylinder 3.

The particles on the bottom of the material distribution cylinder 3 are collected between the arc plate 54 and the cylindrical shell 5 by the arc plate 54, so that the particles are prevented from moving to the edge of the material distribution cylinder 3, meanwhile, the baffle 52 is also facilitated to drive the particles to fall into the blanking pipe 31, and the working efficiency of the baffle 52 is effectively improved.

Specifically, the lifting mechanism comprises a cylindrical supporting block 7, the supporting block 7 is coaxially arranged and is slidably connected to the rotating shaft 2, and an annular groove 741 is formed in the supporting block 7; a threaded rod 71 is arranged on the rack 1, a rocking handle 72 is fixedly arranged at the upper end of the threaded rod 71, and the lower end of the threaded rod 71 is rotatably arranged on the rack 1; a threaded sleeve 73 is connected to the threaded rod 71 in a threaded manner, and connecting rods 74 are respectively arranged on two sides of the threaded sleeve 73; one end of each connecting rod 74 extends to the periphery of the supporting block 7, and the other end of each connecting rod is fixedly connected with the threaded sleeve 73; a pulley 742 is fixedly arranged at the end part of the connecting rod 74 extending to the periphery of the supporting block 7, the pulley 742 extends into the annular groove 741, and the upper edge and the lower edge of the pulley 742 are respectively contacted with the upper inner wall and the lower inner wall of the annular groove 741; a positioning column 75 is further arranged between the two connecting rods 74, the lower end of the positioning column 75 is fixedly arranged on the rack 1, and the upper end of the positioning column 75 is suspended; the positioning column 75 is sleeved with a positioning sleeve 76, and the positioning sleeve 76 is fixedly connected with the two connecting rods 74 respectively.

The rocking handle 72 is rotated, the rocking handle 72 drives the threaded rod 71 to rotate, and the threaded rod 71 drives the two connecting rods 74 to synchronously move up and down through the threaded sleeve 72. Two links 74 carry the support block 7 via a positioning sleeve 76 and a pulley 742. Meanwhile, the supporting block 7 drives the rotating disc 6 to ascend and descend on the rotating shaft 2, and the distance between the upper side face of the rotating disc 6 and the lower side face of the material distributing cylinder 3 is changed, so that the effective volume formed between the blanking pipe 31 and the material collecting pipe 61 is adjusted. When the rotating disk 6 is rotated by the rotating shaft 2, the pulley 742 moves in the annular groove 741.

The effective volume formed between the blanking pipe 31 and the material collecting pipe 61 can be adjusted by rotating the rocking handle 72 in the process, so that the device can adjust the quantity of filling particles, and is simple in structure and convenient to operate.

Specifically, a transparent cover 53 is fixedly arranged on the cylindrical shell 5 around the lower end of the feed hopper 4, and the outer side edge of the transparent cover 53 extends to the periphery of the material separating barrel 3.

The provision of the transparent cover 53 effectively prevents dust from entering the dispensing cartridge 3 and also facilitates the observation of the inside of the dispensing cartridge 3 through the transparent cover 53.

Specifically, two auxiliary stay bars 77 are provided around the periphery of the supporting block 7; the lower end of the auxiliary stay bar 77 is fixed on the supporting block 7 through a fixing plate, and the upper end is provided with a threaded hole 771; the threaded hole 771 is internally connected with an adjusting rod 772, one end of the adjusting rod 772 extends out of the threaded hole 771 and the end of the adjusting rod 772 is pressed on the lower side surface of the rotating disk 6.

The auxiliary stay bar 77 and the adjusting bar 772 are arranged to help the supporting block 7 to stably drive the rotating disc 6 to ascend and descend; the adjustment of the length of the adjustment rod 772 protruding outside the threaded hole 771 is facilitated by the structure in which the adjustment rod 772 is threadedly coupled in the threaded hole 771.

Specifically, a material shielding plate 55 is slidably arranged on the edge of the material scattering port 51, and the size of the material shielding plate 55 is larger than that of the material scattering port 51; the material covering plate 55 is in threaded connection with a pull rod 551; the upper end of the pull rod 551 extends out of the transparent cover 53.

The pull rod 551 is rotated to enable the covering plate 55 to ascend and descend under the driving of the pull rod 551, and the distance between the lower side edge of the covering plate 55 and the lower side edge of the material scattering port 51 is changed, so that the quantity of particles discharged from the material scattering port 51 is adjusted, and the accuracy of the device in particle filling is further improved.

Specifically, the opening and closing mechanism includes a first fixing lever 63 and a second fixing lever 64; the lower ends of the first fixed rod 63 and the second fixed rod 64 are fixed on a connecting rod 74, and the upper ends of the first fixed rod 63 and the second fixed rod 64 are positioned between the lower side surface of the movable cover 62 and the lower side surface of the rotating disc 6; the second fixing lever 64 is located between the first fixing lever 63 of the rotating disk 6 and the supporting block 7 and the second fixing lever 64 is located at the rotation rear side of the first fixing lever 63.

When the movable cover 62 passes the first fixing lever 63, the first fixing lever 63 contacts the movable cover 62 and rotates the movable cover 62 about the pivot 621 toward the supporting block 7, thereby opening the lower port of the material collecting pipe 61 above the movable cover 62 and allowing the particles in the material collecting pipe 61 to fall into the external storage device. As the rotary disk 6 rotates, the second fixing lever 64 contacts the end of the movable cover 62 and rotates the movable cover 62 to the outside about the pivot 621, thereby closing the lower port of the material collecting pipe 61 above the movable cover 62. The structure realizes that the movable cover 62 automatically opens and closes the lower port of the collecting pipe 61, effectively improves the working efficiency of the device, and has simple structure and low cost.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (7)

1. A granule filling machine, includes frame (1), its characterized in that still includes:

a feed hopper (4) fixed on the frame (1);

a cylindrical housing (5) fixed below the lower end of the feed hopper (4); a material spreading port (51) is formed in the lower side edge of the cylindrical shell (5); a baffle plate (52) is fixedly arranged on the cylindrical shell (5);

the material separating barrel (3) is arranged around the periphery of the cylindrical shell (5) through a rotating shaft (2) which is rotatably arranged on the rack (1); a plurality of blanking pipes (31) communicated with the interior of the material separating barrel (3) are uniformly arranged on the bottom of the material separating barrel (3) around the cylindrical shell (5); the outer side edge of the baffle (52) is arranged between the upper end opening of the blanking pipe (31) and the inner wall of the material separating barrel (3); the rack (1) is provided with a driving mechanism capable of driving the rotating shaft (2) to rotate;

the rotating disc (6) is coaxially arranged below the material separating cylinder (3) through a rotating shaft (2), and the rotating disc (6) is provided with material collecting pipes (61) the number of which is the same as that of the blanking pipes (31); the upper ports of the material collecting pipes (61) respectively surround the periphery of the lower port of a blanking pipe (31), and the lower ports penetrate through the lower side surface of the rotating disc (6); the lower side surface of the rotating disc (6) is provided with movable covers (62) with the same number as the material collecting pipes (61) through a pivot (621), and the movable covers (62) are respectively positioned below the lower port of a blanking pipe (31); the frame (1) is provided with an opening and closing mechanism which can drive a movable cover (62) to automatically open and close the lower port of the material collecting pipe (61) when the rotating disc (6) rotates; the rack (1) is also provided with a lifting mechanism which can drive the rotating disc (6) to ascend and descend on the rotating shaft (2).

2. A machine as claimed in claim 1, characterised in that said cylindrical shell (5) is provided with an arc-shaped plate (54), said arc-shaped plate (54) being arranged between the upper end of the collecting pipe (61) and the inner wall of the distribution cylinder (3).

3. The pellet filling machine as claimed in claim 2, wherein said lifting mechanism comprises a cylindrical support block (7), said support block (7) is coaxially arranged and slidably connected to said rotating shaft (2), said support block (7) is provided with an annular groove (741); a threaded rod (71) is arranged on the rack (1), a rocking handle (72) is fixedly arranged at the upper end of the threaded rod (71), and the lower end of the threaded rod (71) is rotatably arranged on the rack (1); the threaded rod (71) is in threaded connection with a threaded sleeve (73), and two sides of the threaded sleeve (73) are respectively provided with a connecting rod (74); one end of each connecting rod (74) extends to the periphery of the supporting block (7), and the other end of each connecting rod is fixedly connected with the threaded sleeve (73); a pulley (742) is fixedly arranged at the end part of the connecting rod (74) extending to the periphery of the supporting block (7), the pulley (742) extends into the annular groove (741), and the upper edge and the lower edge of the pulley (742) are respectively contacted with the upper inner wall and the lower inner wall of the annular groove (741); a positioning column (75) is further arranged between the two connecting rods (74), the lower end of the positioning column (75) is fixedly arranged on the rack (1), and the upper end of the positioning column is suspended; the positioning column (75) is sleeved with a positioning sleeve (76), and the positioning sleeve (76) is fixedly connected with the two connecting rods (74) respectively.

4. A machine as claimed in claim 3, characterised in that a transparent cover (53) is fixed to the cylindrical housing (5) around the lower end of the feed hopper (4), the outer edge of the transparent cover (53) extending to the periphery of the distribution hopper (3).

5. A machine as claimed in claim 4, characterised in that two auxiliary stays (77) are provided around the periphery of the support block (7); the lower end of the auxiliary stay bar (77) is fixed on the supporting block (7) through a fixing plate, and the upper end of the auxiliary stay bar is provided with a threaded hole (771); threaded hole (771) female connection has adjusts pole (772), adjust pole (772) one end and stretch out outside threaded hole (771) and the tip supports and presses on the downside of rotary disk (6).

6. A machine as in claim 5, characterized in that said discharge opening (51) is provided with a shutter (55) sliding on the edge, said shutter (55) being larger than the discharge opening (51); the material covering plate (55) is connected with a pull rod (551) in a threaded manner; the upper end of the pull rod (551) extends out of the transparent cover (53).

7. A machine as claimed in any one of claims 1 to 6, wherein the opening and closing means comprises a first fixed rod (63) and a second fixed rod (64); the lower ends of the first fixing rod (63) and the second fixing rod (64) are uniformly connected with a connecting rod (74), and the upper ends of the first fixing rod (63) and the second fixing rod (64) are positioned between the lower side surface of the movable cover (62) and the lower side surface of the rotating disc (6); the second fixing lever (64) is located between the first fixing lever (63) of the rotating disk (6) and the supporting block (7) and the second fixing lever (64) is located at the rear side of the rotation of the first fixing lever (63).

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