CN213084792U

CN213084792U - Vacuum feeding machine

Info

Publication number: CN213084792U
Application number: CN202021648705.1U
Authority: CN
Inventors: 黄媛; 朱雨倩
Original assignee: Kunshan Supin Food Co ltd
Current assignee: Kunshan Supin Food Co ltd
Priority date: 2020-08-10
Filing date: 2020-08-10
Publication date: 2021-04-30
Anticipated expiration: 2030-08-10

Abstract

The utility model provides a vacuum feeding machine, include: the device comprises a shell, a feed inlet is arranged at the center of a top cover of the shell, and a discharge outlet connected with a vacuum feed pump is arranged on a lower bottom plate of the shell; the screening assembly is arranged on the inner wall of the shell and positioned below the feeding hole, the screening assembly comprises a conical filtering cover, the cone angle of the filtering cover faces downwards, the filtering cover can be arranged on the inner wall of the shell in a vibrating mode, and a vibrating motor used for enabling the filtering cover to vibrate is arranged on the inner wall of the shell; the filter mantle is coaxial with the casing setting, and the surface of filter mantle is equipped with the sieve mesh, and the axle center department of filter mantle is equipped with the particulate matter discharge port, and this particulate matter discharge port lower extreme is connected with the granule and collects the subassembly. The raw materials can be screened and separated, so that the granularity of the raw materials is ensured to have smaller particle size, and the quality of finished products is ensured.

Description

Vacuum feeding machine

Technical Field

The utility model relates to a solid beverage processing production mechanical equipment field, concretely relates to vacuum material loading machine.

Background

Vacuum feeding machines are already common devices, and are dust-free closed pipeline conveying equipment for conveying particles and powder materials by means of vacuum suction, but in the production process of solid beverages, the particle size of the powder needs to be small enough to facilitate the brewing and dissolution of the solid beverages, so if particles with larger particle sizes exist in raw materials, the raw materials are not uniform, the brewing and taste of the solid beverages are affected, and the product quality is caused.

SUMMERY OF THE UTILITY MODEL

For solving the technical problem, the utility model provides a vacuum feeding machine, this material loading machine can carry out the granule screening to the raw materials, can sieve and the material loading to the raw materials of fine particle, can carry out directional collection to the raw materials of coarse grain simultaneously.

The utility model particularly provides a vacuum feeding machine, include: the device comprises a shell, a vacuum feeding pump, a vacuum pump and a vacuum pump, wherein a feeding hole is formed in the center of a top cover of the shell; the screening assembly is arranged on the inner wall of the shell and positioned below the feeding hole, the screening assembly comprises a conical filter cover, the cone angle of the filter cover faces downwards, the filter cover can be arranged on the inner wall of the shell in a vibrating mode, and a vibrating motor used for vibrating the filter cover is arranged on the inner wall of the shell; the filter mantle with the casing is coaxial to be set up, the surface of filter mantle is equipped with the sieve mesh, and the axle center department of filter mantle is equipped with the particulate matter discharge port, and this particulate matter discharge port lower extreme is connected with the granule and collects the subassembly.

Raw materials are input into the shell through the feed inlet, then fall onto the conical filter cover of the screening component, the vibrating motor drives the conical filter cover to vibrate, so that the raw materials are loosened, screened and filtered, and fine-particle materials fall onto the lower bottom plate of the shell and are conveyed to the next process through the discharge outlet by the vacuum feeding pump; the large-particle raw material is collected by the particle collection assembly through the particle discharge port and conveyed to the next process for drying and grinding treatment.

The technical effect of the technical scheme is as follows: the raw materials can be screened and separated, so that the granularity of the raw materials is ensured to have smaller particle size, and the quality of finished products is ensured.

Preferably, the screen assembly with be equipped with the feeding reposition of redundant personnel subassembly between the feed inlet, the feeding reposition of redundant personnel subassembly includes: a gap is reserved between the peripheral surface of the material baffle disc and the inner wall of the shell, and the material baffle disc is fixed on the inner wall of the shell through a support; the material pushing plate is rotatably arranged on the upper surface of the material baffle disc; and the driving motor is arranged on the material blocking disc, and a rotating shaft of the driving motor is fixedly connected with the material pushing plate through a guide hole arranged on the material blocking disc.

After the raw materials fell on the material fender dish, driving motor drove the scraping wings and rotated to realized pushing away the raw materials from the material fender dish and fallen, its purpose: the raw materials fall on the conical filter cover close to the inner wall of the shell, so that the moving stroke of the raw materials on the conical filter cover is lengthened, and the screening efficiency of the raw materials is improved.

Preferably, a material pouring cover is arranged between the material blocking disc and the conical filtering cover, the material pouring cover is of an inverted round platform structure, the upper end and the lower end of the material pouring cover are both of an open structure, the upper end of the material pouring cover is seamlessly fixed on the inner wall of the shell, and the lower end of the material pouring cover is arranged close to the periphery of the material pouring cover; the material pouring cover completely covers a gap between the filter cover and the inner wall of the shell along a vertical downward projection.

The preferable technical effects are as follows: the raw materials are prevented from falling into a crack between the shell and the conical filter cover, so that the screening efficiency of the raw materials is improved.

Preferably, a closed cover is hermetically arranged on the driving motor. The dust-proof device is used for preventing dust in raw materials from entering the driving motor, so that the dust is prevented from influencing the normal use of the driving motor.

Preferably, the lower bottom plate of the shell is a conical plate, and the discharge port is arranged at the conical angle of the lower bottom plate. Which is used to drop the screened material into a discharge port.

Preferably, the side wall of the shell is a honeycomb plate or a double-layer plate with a space. The vibration motor mainly plays a role in reducing noise and is used for silencing the noise generated by the vibration motor.

Preferably, the particle collection assembly comprises: a metal pipe vertically installed at a lower end of the particulate matter discharge port; a particle diverter, an input port of which is mounted at the lower end of the metal pipe; the particle diverter comprises a folding pipe, wherein one end of the folding pipe is installed in a penetrating mode on an output port of the particle diverter, and the other end of the folding pipe is connected with a material vacuum suction pump used for recycling particles. The upper end of granule shunt is equipped with a material input port, is equipped with a storage space with material input port intercommunication in the granule shunt, and the lower extreme of granule shunt is equipped with a plurality of material delivery outlets that link to each other through with storage space.

The preferable technical effects are as follows: through shunting the raw materials of big granule to avoid the tubular metal resonator direct mount can take place to interfere with the discharge gate on the lower plate, avoid the tubular metal resonator to produce to shield the discharge gate.

Preferably, a high-pressure air gun is installed on the inner wall of the shell and is arranged close to the lower bottom plate of the shell, and an air jet of the high-pressure air gun faces the lower bottom plate of the shell.

The preferable technical effects are as follows: the lower bottom plate is used for preventing raw materials on the lower bottom plate from being accumulated, and is convenient for blowing the raw materials on the lower bottom plate to the discharge hole in time.

Preferably, the number of the high-pressure air guns is a plurality, and the high-pressure air guns are uniformly distributed in a circumferential array by taking the axis of the shell as a reference. The preferable technical effects are as follows: the efficiency of raw materials from the discharge gate by being discharged has further been improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the embodiments or the description of the prior art will be briefly described below.

Fig. 1 is a cross-sectional view of a vacuum feeder according to the present invention.

Fig. 2 is a sectional view a-a in fig. 1.

Fig. 3 is a sectional view B-B of fig. 1.

Wherein the reference numbers referred to in the figures are as follows:

1-a shell; 2-a screen assembly; 11-a feed inlet; 12-a discharge hole; 13-a vacuum feed pump; 21-a filter mantle; 22-a vibration motor; 23-sieve mesh; 24-a particulate matter discharge port; 31-material blocking disc; 32-a scaffold; 33-a stripper plate; 34-a drive motor; 35-a closed cover; 41-material pouring cover; 51-a metal tube; 52-a particle diverter; 53-folding a tube; 54-material vacuum pump; 55-high pressure air gun.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As fig. 1 to fig. 3, the utility model provides a vacuum feeding machine, include: the device comprises a shell 1, wherein a feed inlet 11 is formed in the center of a top cover of the shell 1, and a discharge outlet 12 connected with a vacuum feed pump 13 is formed in a lower bottom plate of the shell 1; the screening assembly 2 is mounted on the inner wall of the shell 1, the screening assembly 2 is located below the feeding hole 11, the screening assembly 2 comprises a conical filter cover 21, the cone angle of the filter cover 21 faces downwards, the filter cover 21 can be mounted on the inner wall of the shell 1 in a vibrating mode, and a vibrating motor 22 used for enabling the filter cover 21 to vibrate is mounted on the inner wall of the shell 1; the filter cover 21 is arranged coaxially with the housing 1, the surface of the filter cover 21 is provided with sieve holes 23, the axis of the filter cover 21 is provided with a particulate matter discharge port 24, and the lower end of the particulate matter discharge port 24 is connected with a particle collection assembly.

Raw materials are input into the shell 1 through the feed inlet 11, then fall onto the conical filter cover 21 of the screening component 2, the vibration motor 22 drives the conical filter cover 21 to vibrate, so that the raw materials are loosened, screened and filtered, and fine-particle materials fall onto the lower bottom plate of the shell 1 and are conveyed to the next process through the discharge outlet 12 by the vacuum feeding pump 13; the large particle material is collected by the particle collection assembly through the particle discharge port 24 and conveyed to the next process for drying and grinding.

As an embodiment of the utility model, the screening subassembly 2 with be equipped with feeding reposition of redundant personnel subassembly between the feed inlet 11, feeding reposition of redundant personnel subassembly includes: a gap is reserved between the peripheral surface of the material baffle disc 31 and the inner wall of the shell 1, and the material baffle disc 31 is fixed on the inner wall of the shell 1 through a bracket 32; the material pushing plate 33 is rotatably arranged on the upper surface of the material baffle disc 31; and the driving motor 34 is installed on the material blocking disc 31, and a rotating shaft of the driving motor 34 is fixedly connected with the material pushing plate 33 through a guide hole arranged on the material blocking disc 31.

After the raw materials fell on material fender dish 31, driving motor 34 drove scraping wings 33 and rotated to realized pushing away the raw materials from material fender dish 31 and fallen, its purpose: the raw materials fall on the conical filter cover 21 close to the inner wall of the shell 1, so that the moving stroke of the raw materials on the conical filter cover 21 is lengthened, and the screening efficiency of the raw materials is improved.

As an embodiment of the present invention, a material pouring cover 41 is disposed between the material blocking plate 31 and the conical filtering cover 21, the material pouring cover 41 is an inverted round platform structure, the upper end and the lower end of the material pouring cover 41 are both open structures, the upper end of the material pouring cover 41 is seamlessly fixed on the inner wall of the casing 1, and the lower end of the material pouring cover 41 is disposed near the periphery of the material pouring cover 41; the material pouring hood 41 completely covers the gap between the filter hood 21 and the inner wall of the housing 1 along the vertical downward projection.

The technical effects are as follows: raw materials are prevented from falling into a crack between the shell 1 and the conical filter cover 21, so that the screening efficiency of the raw materials is improved.

As an embodiment of the present invention, the driving motor 34 is provided with a sealing cover 35. Which is used to prevent dust in the raw material from entering the driving motor 34, thereby preventing the dust from affecting the normal use of the driving motor 34.

As an embodiment of the present invention, the lower plate of the casing 1 is a conical plate, and the discharge port 12 is disposed at the conical angle of the lower plate. Which is used to drop the screened material into the discharge 12.

As an embodiment of the present invention, the side wall of the casing 1 is a honeycomb plate or a double-layer plate with a space. Which mainly functions to reduce noise for silencing noise generated from the vibration motor 22.

As an embodiment of the present invention, the particle collecting assembly comprises: a metal pipe 51, the metal pipe 51 being vertically installed at a lower end of the particulate matter discharge port 24; a particle diverter 52, an input port of the particle diverter 52 being mounted at a lower end of the metal pipe 51; and one end of the folding pipe 53 is installed on the output port of the particle splitter 52 in a penetrating manner, and the other end of the folding pipe 53 is connected with a material vacuum pump 54 for recovering the particulate matters. The upper end of granule shunt 52 is equipped with a material input port, is equipped with a storage space with material input port intercommunication in the granule shunt 52, and the lower extreme of granule shunt 52 is equipped with a plurality of material delivery outlets that link to each other with storage space.

The technical effects are as follows: through shunting the raw materials of big granule to avoid tubular metal resonator 51 direct mount can take place to interfere with discharge gate 12 on the lower plate, avoid tubular metal resonator 51 to produce to shield discharge gate 12.

As an embodiment of the present invention, the high pressure air gun 55 is installed on the inner wall of the casing 1, the high pressure air gun 55 is close to the lower bottom plate of the casing 1, and the air jet of the high pressure air gun 55 faces the lower bottom plate of the casing 1.

The technical effects are as follows: is used for preventing the raw materials on the lower bottom plate from being accumulated, and is convenient for blowing the raw materials on the lower bottom plate to the discharge hole 12 in time.

As an embodiment of the present invention, the number of the high pressure air guns 55 is a plurality of, and a plurality of the high pressure air guns 55 are distributed in a circumferential array uniformly on the basis of the axis of the housing 1. The preferable technical effects are as follows: the efficiency of discharging the raw material from the discharge port 12 is further improved.

When the device works, raw materials are input into the shell 1 through the feed inlet 11, then fall onto the conical filter cover 21 of the screening component 2, the vibration motor 22 drives the conical filter cover 21 to vibrate, so that the raw materials are loosened, screened and filtered, and fine-particle materials fall onto the lower bottom plate of the shell 1 and are conveyed to the next working procedure through the discharge outlet 12 by the vacuum feeding pump 13; the large particle material is collected by the particle collection assembly through the particle discharge port 24 and conveyed to the next process for drying and grinding.

For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims

1. A vacuum feeder, comprising:

the device comprises a shell, a vacuum feeding pump, a vacuum pump and a vacuum pump, wherein a feeding hole is formed in the center of a top cover of the shell;

the screening assembly is arranged on the inner wall of the shell and positioned below the feeding hole, the screening assembly comprises a conical filter cover, the cone angle of the filter cover faces downwards, the filter cover can be arranged on the inner wall of the shell in a vibrating mode, and a vibrating motor used for vibrating the filter cover is arranged on the inner wall of the shell;

the filter mantle with the casing is coaxial to be set up, the surface of filter mantle is equipped with the sieve mesh, and the axle center department of filter mantle is equipped with the particulate matter discharge port, and this particulate matter discharge port lower extreme is connected with the granule and collects the subassembly.

2. The vacuum loader of claim 1, characterized in that: the screening subassembly with be equipped with feeding reposition of redundant personnel subassembly between the feed inlet, feeding reposition of redundant personnel subassembly includes:

a gap is reserved between the peripheral surface of the material baffle disc and the inner wall of the shell, and the material baffle disc is fixed on the inner wall of the shell through a support;

the material pushing plate is rotatably arranged on the upper surface of the material baffle disc;

and the driving motor is arranged on the material blocking disc, and a rotating shaft of the driving motor is fixedly connected with the material pushing plate through a guide hole arranged on the material blocking disc.

3. The vacuum loader of claim 2, wherein: a material pouring cover is arranged between the material baffle disc and the conical filter cover, the material pouring cover is of an inverted round platform structure, the upper end and the lower end of the material pouring cover are both of an open structure, the upper end of the material pouring cover is seamlessly fixed on the inner wall of the shell, and the lower end of the material pouring cover is arranged close to the periphery of the material pouring cover; the material pouring cover completely covers a gap between the filter cover and the inner wall of the shell along a vertical downward projection.

4. The vacuum loader of claim 2 or 3, characterized in that: and a closed cover is hermetically arranged on the driving motor.

5. The vacuum loader of claim 1, characterized in that: the lower bottom plate of the shell is a conical plate, and the discharge hole is formed in the conical angle of the lower bottom plate.

6. The vacuum loader of claim 1, characterized in that: the side wall of the shell is a honeycomb plate or a double-layer plate with a space.

7. The vacuum loader of claim 1, characterized in that: the particle collection assembly includes:

a metal pipe vertically installed at a lower end of the particulate matter discharge port;

a particle diverter, an input port of which is mounted at the lower end of the metal pipe;

the particle diverter comprises a folding pipe, wherein one end of the folding pipe is installed in a penetrating mode on an output port of the particle diverter, and the other end of the folding pipe is connected with a material vacuum suction pump used for recycling particles.

8. The vacuum loader of claim 1, characterized in that: the high-pressure air gun is arranged on the inner wall of the shell and close to the lower bottom plate of the shell, and an air jet of the high-pressure air gun faces the lower bottom plate of the shell.

9. The vacuum loader of claim 8, wherein: the high-pressure air guns are distributed in a uniform circumferential array mode by taking the axis of the shell as a reference.