CN220411042U - Negative pressure dust removal several bottling device - Google Patents

Abstract

The utility model provides a negative pressure dust removal granule counting bottling device, which belongs to the technical field of medicine packaging and aims to solve the problems that when a worker fills medicines into a feed hopper, the medicine needs to be lifted, a great deal of physical power is required to be consumed when the medicine is lifted, and fatigue of the worker is easily caused; the movable part is fixedly connected to the upper end surface of the bottling base; the bottling component is fixedly connected to the upper end face of the bottling base; the feeding shield is fixedly connected to the upper end face of the bottling component; the filling material box is fixedly connected to the rear end face of the bottling base; the medicine transmission mechanism is arranged at the rear side of the interior of the bottling base; the transmission vibration mechanism is arranged in the filling box. Adopt medicine transport mechanism, realize making things convenient for the staff to the inside dress medicine of feeding guard shield, adopt transmission vibration mechanism, realize vibrations oblique piece vibrations and shake the medicine on the vibration transmission belt.

Description

Negative pressure dust removal several bottling device

Technical Field

The utility model belongs to the technical field of medicine packaging, and particularly relates to a negative pressure dust removal and particle counting bottling device.

Background

The granular medicine is bottled by using a bottling device when the granular medicine is bottled, the bottling device is used for filling the granules into the bottle through negative pressure, and the bottling device is used for removing dust on the surface of the medicine when the medicine is bottled, so that the cleanliness of the medicine is ensured.

According to CN201711395201.6, the utility model discloses an automatic capsule bottling device, which comprises a base, a sorting mechanism, a dust removing mechanism, a first conveying mechanism, a granule counting mechanism, a second conveying mechanism and a control mechanism, wherein the sorting mechanism comprises a feed inlet, a first capsule screening plate, a second capsule screening plate and a waste capsule receiving barrel, the dust removing mechanism comprises a feed hopper, an ion fan, a dust collection motor, a dust collector and a feed opening, and the granule counting mechanism comprises a granule counting hopper, a filter cylinder and a feed plate. According to the utility model, through the mutual matching of the sorting mechanism, the dust removing mechanism, the first conveying mechanism, the grain counting mechanism and the second conveying mechanism, the sorting, dust removing and bottling operations of capsules are completed at one time, and the product qualification rate is improved; through the mutual cooperation of the first capsule screening plate, the second capsule screening plate and the vibration motor, the qualified capsules and the unqualified capsules are rapidly sorted out; through the mutual cooperation of dust catcher and ion fan, effectively get rid of the tiny dust that the capsule surface adsorbed.

Based on the above, current bottling device generally fills the medicine through the feeder hopper structure, and the feeder hopper is generally installed on bottling device, and convenient medicine flows into bottling device inside, and the staff need lift the medicine when filling the medicine to the feeder hopper, and inside pouring the medicine into the feeder hopper again, the staff need consume a large amount of physical power when lifting the medicine, leads to the staff tired out easily, influences staff's work efficiency.

Disclosure of Invention

In order to solve the technical problems, the utility model provides the negative pressure dust removal granule counting bottling device, so as to solve the problems that the traditional bottling device generally fills medicines through a feeding hopper structure, the feeding hopper is generally arranged on the bottling device, medicines are convenient to flow into the bottling device, a worker needs to lift the medicines when filling the medicines into the feeding hopper, then the medicines are poured into the feeding hopper, a great deal of physical effort is required when the worker lifts the medicines, fatigue is easily caused to the worker, and the working efficiency of the worker is influenced.

The utility model discloses a negative pressure dust removal particle counting bottling device, which is characterized by comprising the following specific technical means:

a negative pressure dust removal particle counting bottling device comprises a bottling base, a moving part, a bottling part, a feeding shield, a bottling display screen, a filling bin, a filling rotating shaft, a drug transmission mechanism and a transmission vibration mechanism; the movable part is fixedly connected to the front side of the upper end surface of the bottling base; the bottling component is fixedly connected to the upper end face of the bottling base; the feeding shield is fixedly connected to the rear side of the upper end face of the bottling component; the bottling display screen is fixedly connected to the right side of the lower end face of the bottling component; the filling material box is fixedly connected to the rear end face of the bottling base; the filling rotating shaft is rotationally connected inside the filling material box; the medicine transmission mechanism is arranged at the rear side of the interior of the bottling base; the transmission vibration mechanism is arranged in the filling box.

Further, the medicine transmission mechanism comprises: a filling motor and a filling guard board; the filling motor is fixedly connected to the front side of the right end face of the filling material box, and the filling motor rotating shaft is coaxially and fixedly connected with the filling rotating shaft; the filling guard plates are provided with two groups, the two filling guard plates are respectively and fixedly connected inside the rear side of the bottling base, and the filling rotating shaft is rotationally connected with the two filling guard plates.

Further, the medicine transmission mechanism further comprises: a lower belt pulley, an upper belt pulley and a filling transmission belt; the lower belt wheel is rotationally connected to the lower sides of the inner parts of the two assembly filling protection plates, and is fixedly connected with the filling rotating shaft coaxially; the upper belt wheel is rotatably connected to the upper sides of the interiors of the two assembly filling guard plates; the filling driving belt is connected to the lower belt pulley and the upper belt pulley in a driving way.

Further, the transmission vibration mechanism comprises: a main shaft belt wheel, a vibration transmission belt and a vibration belt wheel; the main shaft belt wheel is coaxially and fixedly connected to the filling rotating shaft; the vibration belt wheel is rotationally connected to the right side inside the filling material box; the vibration transmission belt is in transmission connection with the main shaft belt wheel and the vibration belt wheel, and the vibration transmission belt is in the filling material box.

Further, the transmission vibration mechanism further comprises: a vibration rotating shaft and a vibration cam; the vibration rotating shaft is rotationally connected inside the filling material box, and is fixedly connected with the vibration belt wheel coaxially; the vibration cam is fixedly connected to the vibration rotating shaft.

Further, the transmission vibration mechanism further comprises: a vibrating sloping block and a vibrating spring; the vibration inclined block is connected in the filling box in a sliding manner, is positioned at the rear side of the vibration transmission belt and is positioned at the upper side of the vibration cam; the vibration springs are provided with a plurality of groups, the vibration springs are respectively and fixedly connected in the filling material box, and the vibration springs are respectively and elastically connected with the lower end face of the vibration inclined block.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, by adopting the medicine conveying mechanism, when medicines are filled into the feeding shield, the medicines are poured into the filling box by a worker, and are conveyed to the vibration transmission belt by the vibration transmission belt, so that the problem that the medicines are lifted up by the worker to be poured into the filling box is avoided, the medicines are conveniently filled into the feeding shield by the worker, the physical strength of the worker is saved, and the operation of the worker is facilitated.

According to the utility model, by adopting the transmission vibration mechanism, when the vibration transmission belt is used for charging the medicine in the charging bin, the vibration oblique block vibrates, and the vibration oblique block vibrates to vibrate the medicine on the vibration transmission belt, so that the problem that the medicine is stuck on the inner wall due to certain viscosity of the medicine is avoided, and meanwhile, the stuck medicine is firstly vibrated, so that the medicine is ensured to be transmitted to the inside of the charging shield, and the quality of bottling the medicine by the bottling device is ensured.

Drawings

Fig. 1 is a schematic diagram of the front view of the bottling apparatus of the present utility model.

Fig. 2 is a schematic rear view of the bottling apparatus according to the utility model.

Fig. 3 is a schematic view of the structure of the feeding of the bottling device according to the utility model.

Fig. 4 is a schematic view of the feeding transmission structure of the bottling device of the present utility model.

Fig. 5 is a schematic view of the structure of the drug delivery mechanism of the present utility model.

Fig. 6 is a schematic structural view of the transmission vibration mechanism of the present utility model.

In the figure, the correspondence between the component names and the drawing numbers is:

1. bottling the base; 101. filling a guard board; 2. a moving member; 3. bottling the component; 4. a feed shield; 5. bottling the display screen; 6. filling a feed box; 7. filling a motor; 8. filling a rotating shaft; 801. a spindle pulley; 802. vibrating the transmission belt; 9. a lower belt wheel; 10. an upper belt wheel; 11. filling a transmission belt; 12. vibrating the rotating shaft; 1201. vibrating belt wheels; 1202. a vibrating cam; 13. vibrating the oblique block; 1301. and (5) vibrating the spring.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Embodiment one:

as shown in fig. 1 to 5:

the utility model provides a negative pressure dust removal granule counting bottling device which comprises a bottling base 1, a movable part 2, a bottling part 3, a feeding shield 4, a bottling display screen 5, a filling material box 6, a filling rotating shaft 8 and a medicine conveying mechanism; the movable part 2 is fixedly connected to the front side of the upper end surface of the bottling base 1; the bottling component 3 is fixedly connected to the upper end face of the bottling base 1; the feeding shield 4 is fixedly connected to the rear side of the upper end face of the bottling part 3; the bottling display screen 5 is fixedly connected to the right side of the lower end face of the bottling component 3; the filling material box 6 is fixedly connected to the rear end face of the bottling base 1; the filling rotating shaft 8 is rotatably connected inside the filling material box 6; the medicine conveying mechanism is arranged at the rear side inside the bottling base 1.

Wherein, medicine transport mechanism includes: a loading motor 7 and a loading guard plate 101; the filling motor 7 is fixedly connected to the front side of the right end face of the filling material box 6, and the rotating shaft of the filling motor 7 is coaxially and fixedly connected with the filling rotating shaft 8; the filling guard plates 101 are provided with two groups, the two filling guard plates 101 are respectively and fixedly connected inside the rear side of the bottling base 1, the filling rotating shaft 8 is rotationally connected with the two filling guard plates 101, and in the use process, the rotating shaft of the filling motor 7 rotates to drive the filling rotating shaft 8 to rotate.

Wherein, medicine transport mechanism still includes: a lower pulley 9, an upper pulley 10, and a loading belt 11; the lower belt wheel 9 is rotationally connected to the lower sides inside the two assembly filling guard plates 101, and the lower belt wheel 9 is fixedly connected with the filling rotating shaft 8 in a coaxial manner; the upper belt wheel 10 is rotatably connected to the upper sides of the interiors of the two assembly filling guard plates 101; the filling transmission belt 11 is in transmission connection with the lower belt pulley 9 and the upper belt pulley 10, and in the use process, the filling rotating shaft 8 rotates to drive the lower belt pulley 9 to rotate, the lower belt pulley 9 rotates to drive the filling transmission belt 11 to transmit, and the filling transmission belt 11 transmits to drive the upper belt pulley 10 to rotate.

Specific use and action of the first embodiment:

in the use process, the rotation of the rotating shaft of the filling motor 7 drives the filling rotating shaft 8 to rotate, the rotation of the filling rotating shaft 8 drives the lower belt pulley 9 to rotate, the lower belt pulley 9 rotates to drive the filling transmission belt 11 to drive, and the filling transmission belt 11 drives the upper belt pulley 10 to rotate, so that the filling transmission belt 11 transmits medicines filled in the material box 6 to the inside of the feeding shield 4.

Embodiment two:

on the basis of the first embodiment, as shown in fig. 6:

still including transmission vibration mechanism, transmission vibration mechanism sets up inside filling workbin 6, and transmission vibration mechanism is including: a spindle pulley 801, a vibration transmission belt 802, and a vibration pulley 1201; the main shaft belt pulley 801 is coaxially and fixedly connected to the filling rotating shaft 8; the vibration belt wheel 1201 is rotatably connected to the right side inside the filling box 6; the vibration transmission belt 802 is in transmission connection with the main shaft belt pulley 801 and the vibration belt pulley 1201, the vibration transmission belt 802 is in transmission inside the filling box 6, in the use process, the filling rotating shaft 8 rotates to drive the main shaft belt pulley 801 to rotate, the main shaft belt pulley 801 rotates to drive the vibration transmission belt 802 to transmit, and the vibration transmission belt 802 drives the vibration belt pulley 1201 to rotate.

Wherein, transmission vibration mechanism still includes: a vibration spindle 12 and a vibration cam 1202; the vibration rotating shaft 12 is rotatably connected inside the filling box 6, and the vibration rotating shaft 12 is fixedly connected with the vibration belt wheel 1201 in a coaxial manner; the vibration cam 1202 is fixedly connected to the vibration rotating shaft 12, and in the use process, the vibration pulley 1201 rotates to drive the vibration rotating shaft 12 to rotate, and the vibration rotating shaft 12 rotates to drive the vibration cam 1202 to rotate.

Wherein, transmission vibration mechanism still includes: a vibrating swash block 13 and a vibrating spring 1301; the vibration inclined block 13 is connected in the filling box 6 in a sliding way, the vibration inclined block 13 is positioned at the rear side of the vibration transmission belt 802, and the vibration inclined block 13 is positioned at the upper side of the vibration cam 1202; the vibration springs 1301 are provided with a plurality of groups, the vibration springs 1301 are fixedly connected inside the filling box 6 respectively, the vibration springs 1301 are elastically connected with the lower end face of the vibration inclined block 13 respectively, in the use process, the vibration cam 1202 rotates to drive the vibration inclined block 13 to slide, the vibration inclined block 13 slides to drive the vibration springs 1301 to stretch, and the vibration springs 1301 and the vibration cam 1202 drive the vibration inclined block 13 to slide reciprocally.

Specific use and action of the second embodiment:

in the use process, the filling rotating shaft 8 rotates to drive the main shaft belt pulley 801 to rotate, the main shaft belt pulley 801 rotates to drive the vibration transmission belt 802 to drive, the vibration transmission belt 802 drives the vibration belt pulley 1201 to rotate, the vibration belt pulley 1201 rotates to drive the vibration rotating shaft 12 to rotate, the vibration rotating shaft 12 rotates to drive the vibration cam 1202 to rotate, the vibration cam 1202 rotates to drive the vibration inclined block 13 to slide, the vibration inclined block 13 slides to drive the vibration spring 1301 to stretch out and draw back, the vibration spring 1301 and the vibration cam 1202 drive the vibration inclined block 13 to slide reciprocally, and the purpose that the vibration inclined block 13 vibrates to vibrate medicines on the vibration inclined block 13 to the filling transmission belt 11 is achieved.

Claims (6)

1. The utility model provides a negative pressure dust removal several bottling device which characterized in that: the device comprises a bottling base (1), a moving part (2), a bottling part (3), a feeding shield (4), a bottling display screen (5), a filling box (6), a filling rotating shaft (8), a medicine transmission mechanism and a transmission vibration mechanism; the movable part (2) is fixedly connected to the front side of the upper end face of the bottling base (1); the bottling component (3) is fixedly connected to the upper end face of the bottling base (1); the feeding shield (4) is fixedly connected to the rear side of the upper end face of the bottling component (3); the bottling display screen (5) is fixedly connected to the right side of the lower end face of the bottling component (3); the filling box (6) is fixedly connected to the rear end face of the bottling base (1); the filling rotating shaft (8) is rotatably connected inside the filling material box (6); the medicine transmission mechanism is arranged at the rear side of the interior of the bottling base (1); the transmission vibration mechanism is arranged in the filling box (6).

2. The negative pressure dust removal several bottling device according to claim 1, wherein: the medicine transmission mechanism comprises: a loading motor (7) and a loading guard plate (101); the filling motor (7) is fixedly connected to the front side of the right end face of the filling material box (6), and the rotating shaft of the filling motor (7) is coaxially and fixedly connected with the filling rotating shaft (8); the filling guard plates (101) are provided with two groups, the two filling guard plates (101) are respectively and fixedly connected inside the rear side of the bottling base (1), and the filling rotating shaft (8) is rotationally connected with the two filling guard plates (101).

3. The negative pressure dust removal several bottling device according to claim 2, wherein: the medicine transmission mechanism also comprises: a lower belt pulley (9), an upper belt pulley (10) and a loading belt (11); the lower belt wheel (9) is rotationally connected to the lower sides inside the two assembly filling guard plates (101), and the lower belt wheel (9) is fixedly connected with the filling rotating shaft (8) in a coaxial manner; the upper belt wheel (10) is rotatably connected to the upper sides of the interiors of the two assembly filling guard plates (101); the filling transmission belt (11) is connected to the lower belt pulley (9) and the upper belt pulley (10) in a transmission way.

4. The negative pressure dust removal several bottling device according to claim 1, wherein: the transmission vibration mechanism comprises: a main shaft belt wheel (801), a vibration transmission belt (802) and a vibration belt wheel (1201); the main shaft belt wheel (801) is coaxially and fixedly connected to the filling rotating shaft (8); the vibration belt wheel (1201) is rotatably connected to the right side inside the filling box (6); the vibration transmission belt (802) is in transmission connection with the main shaft belt wheel (801) and the vibration belt wheel (1201), and the vibration transmission belt (802) is in transmission inside the filling box (6).

5. The negative pressure dust removal several bottling device according to claim 4, wherein: the transmission vibration mechanism further comprises: a vibrating shaft (12) and a vibrating cam (1202); the vibration rotating shaft (12) is rotationally connected inside the filling bin (6), and the vibration rotating shaft (12) is fixedly connected with the vibration belt wheel (1201) in a coaxial manner; the vibration cam (1202) is fixedly connected to the vibration rotating shaft (12).

6. The negative pressure dust removal several bottling device according to claim 5, wherein: the transmission vibration mechanism further comprises: a vibrating sloping block (13) and a vibrating spring (1301); the vibrating inclined block (13) is connected inside the filling box (6) in a sliding way, the vibrating inclined block (13) is positioned at the rear side of the vibrating transmission belt (802), and the vibrating inclined block (13) is positioned at the upper side of the vibrating cam (1202); the vibrating springs (1301) are provided with a plurality of groups, the vibrating springs (1301) are respectively and fixedly connected inside the filling box (6), and the vibrating springs (1301) are respectively and elastically connected with the lower end face of the vibrating inclined block (13).