CN220298812U - Infrared dynamic scanning type automatic grain counting machine - Google Patents

Abstract

The utility model provides an infrared dynamic scanning type automatic grain counting machine. The automatic grain counting machine of infrared dynamic scanning formula includes automatic grain counting machine body to and base and the feeder hopper of setting on automatic grain counting machine body, one side fixed mounting of base has the supporting seat, the top fixed mounting of supporting seat has two box bodies, two all rotate in the box body and install vertical screw rod, two the bottom of vertical screw rod all runs through the supporting seat and with supporting seat swing joint, two the same loading board is installed to the screw thread on the vertical screw rod, the top of loading board is equipped with the slip table, the top fixed mounting of slip table has riser one and riser two, rotate on riser one and the riser two and install same storage vat. The infrared dynamic scanning type automatic grain counting machine provided by the utility model has the advantages of no need of artificial ascending and dumping, potential safety hazard reduction and convenience in operation.

Description

Infrared dynamic scanning type automatic grain counting machine

Technical Field

The utility model relates to the technical field of particle counting machines, in particular to an infrared dynamic scanning type automatic particle counting machine.

Background

The infrared dynamic scanning type automatic tablet counting machine inputs a working signal generated by an infrared dynamic scanning sensor into an FPGA high-speed microprocessor when the tablet falls down by adopting the principle of a photoelectric effect, realizes a counting function by matching a circuit and a program, and transmits the tablet one by one without overlapping phenomenon, so that the tablet loading amount can be ensured as much as possible.

However, in practical use, the tablet counting machine discovers that the feeding hopper for charging is at the highest position of the whole equipment, so that each time the drug particles in the discharging hopper are consumed, the drug particles need to climb on the ascending ladder manually and then be lifted up to be poured into the feeding hopper, and the ascending type material pouring process can bring certain potential safety hazards to workers, and the workers can not stably lift up the drug barrel to pour the drug at the high position, so that the tablet counting machine is inconvenient to use.

Therefore, it is necessary to provide a new infrared dynamic scanning type automatic particle counter to solve the above technical problems.

Disclosure of Invention

The utility model solves the technical problem of providing the infrared dynamic scanning type automatic grain counting machine which does not need artificial ascending and dumping, reduces potential safety hazards and is convenient to operate.

In order to solve the technical problems, the infrared dynamic scanning type automatic grain counting machine provided by the utility model comprises: automatic tablet counting machine body to and set up base and the feeder hopper on automatic tablet counting machine body, one side fixed mounting of base has the supporting seat, the top fixed mounting of supporting seat has two box bodies, two all rotate in the box body and install vertical screw rod, two the bottom of vertical screw rod all runs through the supporting seat and with supporting seat swing joint, two install same loading board on the vertical screw rod screw thread, the top of loading board is equipped with the slip table, the top fixed mounting of slip table has riser one and riser two, rotate on riser one and riser two and install same storage vat, one side of riser one is equipped with closes the lid, the one end of storage vat extends to in closing the lid, just set up the bin outlet one on the storage vat, set up bin outlet two on closing the lid, bin outlet one and bin outlet two looks adaptation.

Preferably, a frame seat is arranged between the bearing plate and the sliding table, the bottom of the sliding table is contacted with the top of the frame seat, a transverse screw rod is rotatably installed in the frame seat, a sliding seat is installed on the transverse screw rod in a threaded manner, the top of the sliding seat is fixedly connected with the sliding table, and the sliding seat is in sliding connection with the top of the frame seat.

Preferably, the top fixed mounting of loading board has the supporting shoe, articulated on the supporting shoe has loose joint piece one, loose joint piece one the top with frame seat fixed connection, one side fixed mounting of loading board has the pneumatic cylinder, articulated on the output shaft of pneumatic cylinder has loose joint piece two, loose joint piece two the top with frame seat sliding connection.

Preferably, the bottom fixed mounting of supporting seat has motor one, motor one's output shaft and corresponding all fixed cover is equipped with gear one on the vertical screw rod, two gear one meshes mutually, two all fixed cover is equipped with the synchronizing wheel on the vertical screw rod, two cover is equipped with same hold-in range on the synchronizing wheel.

Preferably, a second motor is fixedly installed on the outer wall of one side of the frame seat, and an output shaft of the second motor is fixedly connected with one end of the transverse screw rod.

Preferably, the second riser is rotatably provided with a rotating shaft, the rotating shaft and the storage barrel are fixedly sleeved with a second gear, the second gear is meshed with the second gear, one side of the second riser is fixedly provided with a third motor, an output shaft of the third motor is fixedly connected with one end of the rotating shaft, the top of the first riser is fixedly provided with a connecting strip, the connecting strip is fixedly connected with the closing cover, one side of the storage barrel is fixedly provided with a dumping pipe, and a threaded cover is sleeved on the dumping pipe.

Preferably, a cross rod is fixedly installed at the bottom of the frame seat, penetrates through the second loose joint block and is in sliding connection with the second loose joint block.

Compared with the related art, the infrared dynamic scanning type automatic grain counting machine provided by the utility model has the following beneficial effects:

the utility model provides an infrared dynamic scanning type automatic granule counting machine, which can store more granules through a storage barrel which is arranged at one time, when the granules are added into a feed hopper, only a hydraulic cylinder is required to be started, so that the storage barrel is in an inclined state, a motor III is started, a first discharge port and a second discharge port are correspondingly formed, the granules in the storage barrel can enter the feed hopper, thus the feeding work is completed, and when a sufficient quantity of granules are re-filled into the storage barrel each time, only the motor I is required to be started, the storage barrel is brought down to a lower position, so that people can conveniently fill the granules on the ground, the filling on the ground is more convenient and stable, the whole process does not need to perform manual ascending operation, and the potential safety hazard is greatly reduced.

Drawings

FIG. 1 is a schematic diagram of an infrared dynamic scanning automatic particle counter according to a preferred embodiment of the present utility model;

FIG. 2 is a schematic rear view of the present utility model;

FIG. 3 is a schematic diagram of a connection structure of a carrier plate, a frame base and a storage bucket according to the present utility model;

fig. 4 is a schematic side view of the connection structure of the support base and the two boxes in the present utility model.

Reference numerals in the drawings: 1. an automatic grain counting machine body; 2. a base; 3. a feed hopper; 4. a support base; 5. a case body; 6. a vertical screw; 7. a carrying plate; 8. a frame base; 9. a sliding table; 10. a first vertical plate; 11. a second vertical plate; 12. a storage barrel; 13. closing the cover; 14. a first discharge hole; 15. a second discharge hole; 16. a transverse screw; 17. a slide; 18. a support block; 19. a movable joint block I; 20. a hydraulic cylinder; 21. and a movable joint block II.

Detailed Description

The utility model will be further described with reference to the drawings and embodiments.

Referring to fig. 1, fig. 2, fig. 3 and fig. 4 in combination, fig. 1 is a schematic structural diagram of a preferred embodiment of an infrared dynamic scanning automatic particle counter according to the present utility model;

FIG. 2 is a schematic rear view of the present utility model; FIG. 3 is a schematic diagram of a connection structure of a carrier plate, a frame base and a storage bucket according to the present utility model; fig. 4 is a schematic side view of the connection structure of the support base and the two boxes in the present utility model. The infrared dynamic scanning type automatic grain counting machine comprises: the automatic grain counting machine body 1 with the model of SED-8S is characterized in that a base 2 and a feed hopper 3 are further arranged on the automatic grain counting machine body 1, a supporting seat 4 is fixed on one side of the base 2, two box bodies 5 are fixed on the top of the base 2, vertical screws 6 are rotatably installed in the two box bodies 5, the bottom ends of the two vertical screws 6 penetrate through the supporting seat 4 and are movably connected with the supporting seat 4, in order to enable the two vertical screws 6 to rotate simultaneously, a motor I is fixed on the bottom of the supporting seat 4, a gear I is fixedly sleeved on an output shaft of the automatic grain counting machine body and the corresponding vertical screws 6, the two gears I are meshed, a synchronous wheel is fixedly sleeved on the two vertical screws 6, the two synchronous wheels are sleeved with the same synchronous belt, in such a way that the motor I can be started, the two vertical screws 6 rotate simultaneously, the two vertical screws 6 are provided with the same bearing plate 7 in a threaded mode, in order to ensure stable linear lifting of the bearing plate 7, vertical rods are fixedly arranged in the two box bodies 5, the two vertical rods penetrate through the bearing plate 7 and are connected with the bearing plate 7 in a sliding mode, a first vertical cover 13 is formed on the two vertical cover 13, a vertical cover 13 is formed on one side of the two vertical cover 13, a vertical cover 13 is formed on one side of the two vertical cover 13, a 13 is arranged on the two vertical cover 13, a 13 is correspondingly, a 13 is formed, a 13 top 13 is matched with the two vertical cover 13, and a 13 is arranged on the top 13, and a 13 is matched with the top 13, and a 13 is formed 13, so that the pellets in the storage basket 12 can fall out.

In the above mode, in order to drive the storage bucket 12 to move horizontally, the first discharge port 14 and the second discharge port 15 can move to the upper part of the feed hopper 3, a frame seat 8 is arranged between the bearing plate 7 and the sliding table 9, the bottom of the sliding table 9 is contacted with the top of the frame seat 8, a transverse screw 16 is rotatably mounted in the frame seat 8, a sliding seat 17 is mounted on the transverse screw 16 in a threaded manner, the top of the sliding seat 17 is fixedly connected with the sliding table 9, a sliding opening is formed in the top of the frame seat 8, the top of the sliding seat 17 is positioned in the sliding opening, in addition, in order to ensure that the sliding seat 17 can only slide linearly and horizontally, two cross bars are fixed in the frame seat 8, and both cross bars penetrate through the sliding seat 17 and are in sliding relation with the sliding seat 17, in addition, a second motor is fixed on the outer wall of one side of the frame seat 8, and the output shaft of the second motor is fixedly connected with one end of the transverse screw 16.

In this mode, in order to be able to push the storage vat 12 to the inclined state, so that the medicine particles in the storage vat can smoothly fall down, a supporting block 18 is fixed at the top of the bearing plate 7, a movable joint block 19 is hinged on the supporting block 18, the top of the movable joint block 19 is fixedly connected with the frame seat 8, a hydraulic cylinder 20 is fixed at one side of the bearing plate 7, a movable joint block two 21 is hinged on the output shaft of the bearing plate, a cross rod is fixed at the bottom of the frame seat 8, the cross rod penetrates through the movable joint block two 21 and is in sliding connection with the movable joint block two 21, and in order to prevent the hydraulic cylinder 20 from colliding with the supporting seat 4 when falling to the lowest position, a yielding opening is formed in the supporting seat 4, and the caliber of the yielding opening is large, so that the hydraulic cylinder 20 passes through the yielding opening completely.

In this mode, in order to drive the storage vat 12 to rotate, rotate and install the pivot on riser two 11, all fixed cover is equipped with gear two on pivot and the storage vat 12, two gears two-phase meshing, and be fixed with motor three in one side of riser two 11, its output shaft and the one end fixed connection of pivot, and be fixed with the connecting strip at the top of riser one 10, connecting strip and closing 13 fixed connection, one side of storage vat 12 is fixed with emptys the pipe to screw thread cover is equipped with above that.

The working principle of the infrared dynamic scanning type automatic grain counting machine provided by the utility model is as follows:

when bottling, the first motor is reversely started, the output shaft of the first motor is meshed with the first gears to drive the corresponding vertical screw rods 6 to rotate, and meanwhile, the two vertical screw rods 6 are driven to rotate simultaneously by utilizing the transmission between the synchronous wheels and the synchronous belts, so that under the threaded relationship of the vertical screw rods 6 and the bearing plate 7, the bearing plate 7 drives the frame seat 8 and the storage barrel 12 to descend until the bearing plate 7 descends to the lowest position, at the moment, the dumping pipe on the storage barrel 12 is approximately at the height of the thighs of a person, then, the screw cap on the dumping pipe is screwed out, and then a worker takes out the medicine barrel to pour medicine granules into the storage barrel 12 directly from the dumping pipe;

after a certain amount of the material is poured into the container, the screw cap can be screwed on again, then the motor I is started in the forward direction, the bearing plate 7 carries the frame seat 8 and the material storage barrel 12 to ascend, the motor I is closed after the material storage barrel 12 ascends to a height higher than that of the material feeding hopper 3, then the motor II is started in the forward direction, the output shaft of the motor II drives the transverse screw 16 to rotate, at this moment, the sliding table 9 carries the material storage barrel 12 to move towards the material feeding hopper 3 by utilizing the threaded relation between the sliding table and the sliding seat 17, finally, the material discharging opening II 15 on the closing cover 13 corresponds to the material feeding hopper 3 from top to bottom, then, the output shaft of the hydraulic cylinder 20 is started to extend, the frame seat 8 carries out circular motion by taking the hinging position of the supporting block 18 and the movable joint block I19 as a circle center, and finally, the material storage barrel 12 is in an inclined state correspondingly;

then, the output shaft of the motor III is started to drive the rotating shaft to rotate, at the moment, under the meshing of the two gears II, the storage barrel 12 starts to rotate until the storage barrel 12 rotates 180 degrees, the motor III is closed, at the moment, the first discharge port 14 corresponds to the second discharge port 15, medicine particles in the motor III can smoothly enter the feed hopper 3 through the first discharge port 14 and the second discharge port 15 until a certain amount of medicine particles are filled in the feed hopper 3, and then the motor III is started again, so that the storage barrel 12 is brought back to the original state, and the feeding work is not performed until the next feeding work is needed in the feed hopper 3, and the feeding can be continued according to the steps, so that the feeding is repeated;

after the medicine particles in the storage barrel 12 are poured, the storage barrel 12 is driven downwards again according to the reverse operation, and a certain amount of medicine particles are added into the storage barrel again.

Compared with the related art, the infrared dynamic scanning type automatic grain counting machine provided by the utility model has the following beneficial effects:

the utility model provides an infrared dynamic scanning type automatic granule counting machine, which can be used for storing more granules through a storage barrel 12 arranged at one time, when the granules are added into a feed hopper 3, the storage barrel 12 is in an inclined state by only starting a hydraulic cylinder 20, a motor III is started, a first discharge port 14 and a second discharge port 15 are correspondingly formed, the granules in the storage barrel can enter the feed hopper 3, thus the feeding work is completed, and when a sufficient quantity of granules are re-filled into the storage barrel 12 each time, the first motor is started, the storage barrel 12 is brought down to a lower position, so that the feeding of the granules on the ground is facilitated, the feeding on the ground is more convenient and stable, the whole process does not need to perform manual ascending operation, and the potential safety hazard is greatly reduced.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. The utility model provides an infrared dynamic scanning formula automatic grain counting machine, includes automatic grain counting machine body to and base and the feeder hopper of setting on automatic grain counting machine body, its characterized in that, one side fixed mounting of base has the supporting seat, the top fixed mounting of supporting seat has two box bodies, two all rotate in the box body and install vertical screw rod, two the bottom of vertical screw rod all runs through the supporting seat and with supporting seat swing joint, two the same loading board is installed to the screw thread on the vertical screw rod, the top of loading board is equipped with the slip table, the top fixed mounting of slip table has riser one and riser two, rotate on riser one and the riser two and install same storage vat, one side of riser one is equipped with closes the lid, the one end of storage vat extends to in closing the lid, just set up the bin first on the storage vat, set up bin second on closing the lid, bin first and bin two looks adaptation.

2. The infrared dynamic scanning type automatic grain counting machine according to claim 1, wherein a frame seat is arranged between the bearing plate and the sliding table, the bottom of the sliding table is in contact with the top of the frame seat, a transverse screw is rotatably installed in the frame seat, a sliding seat is installed on the transverse screw in a threaded manner, the top of the sliding seat is fixedly connected with the sliding table, and the sliding seat is in sliding connection with the top of the frame seat.

3. The infrared dynamic scanning type automatic grain counting machine according to claim 2, wherein a supporting block is fixedly arranged at the top of the bearing plate, a first loose joint block is hinged to the supporting block, the top of the first loose joint block is fixedly connected with the frame seat, a hydraulic cylinder is fixedly arranged at one side of the bearing plate, a second loose joint block is hinged to an output shaft of the hydraulic cylinder, and the top of the second loose joint block is in sliding connection with the frame seat.

4. The infrared dynamic scanning type automatic grain counting machine according to claim 1, wherein a first motor is fixedly installed at the bottom of the supporting seat, a first gear is fixedly sleeved on an output shaft of the first motor and the corresponding vertical screw rod, the first gears are meshed, a synchronizing wheel is fixedly sleeved on the two vertical screw rods, and the same synchronizing belt is sleeved on the two synchronizing wheels.

5. The infrared dynamic scanning automatic grain counting machine according to claim 2, wherein a second motor is fixedly installed on the outer wall of one side of the frame seat, and an output shaft of the second motor is fixedly connected with one end of the transverse screw rod.

6. The infrared dynamic scanning type automatic grain counting machine according to claim 1, wherein a rotating shaft is rotatably arranged on the second vertical plate, a gear two is fixedly sleeved on each of the rotating shaft and the storage barrel, the two gears are meshed, a motor three is fixedly arranged on one side of the second vertical plate, an output shaft of the motor three is fixedly connected with one end of the rotating shaft, a connecting strip is fixedly arranged on the top of the first vertical plate, the connecting strip is fixedly connected with the closing cover, a dumping pipe is fixedly arranged on one side of the storage barrel, and a threaded cover is sleeved on the dumping pipe.

7. The infrared dynamic scanning automatic grain counting machine according to claim 3, wherein a cross rod is fixedly installed at the bottom of the frame seat, and penetrates through the second loose joint block and is in sliding connection with the second loose joint block.