CN107232982B

CN107232982B - Powder discharging device for high-viscosity powder of multifunctional beverage machine

Info

Publication number: CN107232982B
Application number: CN201710307296.5A
Authority: CN
Inventors: 周利
Original assignee: Changzhou Pilot Electronic Co ltd
Current assignee: Changzhou Pilot Electronic Co ltd
Priority date: 2017-02-22
Filing date: 2017-05-04
Publication date: 2023-08-18
Anticipated expiration: 2037-05-04
Also published as: CN107232982A

Abstract

The invention relates to a powder discharging device of high-viscosity powder of a multifunctional beverage machine, which comprises a powder discharging chute, a stirrer, a charging barrel, a stirring base and a powder discharging rod, wherein the stirrer is arranged in the charging barrel, the stirring base is arranged at the bottom of the charging barrel, the powder discharging rod is arranged in the stirring base, the powder discharging chute is arranged at a powder discharging port at the front end of the stirring base, and the stirrer and the powder discharging rod simultaneously rotate to push out the powder in the charging barrel and discharge the powder through the powder discharging chute. Can effectively cope with various oily or high-viscosity powder, the powder is not easy to accumulate at a powder outlet, normal powder discharging is ensured, the powder discharging precision is ensured, and the powder discharging utilization rate of the powder is improved.

Description

Powder discharging device for high-viscosity powder of multifunctional beverage machine

Technical Field

The invention relates to the technical field of multifunctional beverage machines, in particular to a powder outlet device of high-viscosity powder of a multifunctional beverage machine.

Background

At present, the traditional powder discharging device of the multifunctional beverage machine in the market adopts a mode of matching a gear with a spiral line powder discharging rod to discharge powder, when oil-containing or viscous powder is used, the powder discharging precision cannot be ensured, the powder is easy to adhere to the inner wall of a powder box, and the powder discharging utilization rate is extremely low. And powder is easy to accumulate at the powder outlet, so that normal powder outlet is affected.

Disclosure of Invention

The invention aims to solve the technical problems that: in order to overcome the defects in the prior art, the powder outlet device of the high-viscosity powder of the multifunctional beverage machine, which can effectively cope with various oily or high-viscosity powder.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a powder device of multi-functional beverage machine high viscosity powder, has a powder chute, agitator, feed cylinder, stirring base and goes out the powder pole, the agitator install in the feed cylinder, the stirring base is installed in the bottom of feed cylinder, go out the powder pole and install in the stirring base, go out the powder chute and install in the front end play powder mouth department of stirring base, agitator and play powder pole are rotatory simultaneously and are released the powder in the feed cylinder and fall out via a powder chute.

Further specifically, in the above technical scheme, the stirring column of agitator on densely distributed have a plurality of puddlers that are used for evenly scattering powder in the feed cylinder, a plurality of puddlers are including being located the upper half of stirring column and being used for supporting a plurality of upper puddlers of powder in the feed cylinder and being located the lower half of stirring column and being used for pushing down a plurality of lower puddlers of powder in the feed cylinder.

More specifically, in the above technical scheme, the bottom of the stirring column is further provided with a first scattering mechanism for scattering the powder in the stirring base.

In the technical scheme, the front end of the powder outlet rod is further provided with a second scattering mechanism for scattering powder in the powder outlet chute.

Further specifically, in the above technical scheme, the feed cylinder mainly comprises a cylindrical feeding cylinder section, a conical middle cylinder section and a cylindrical discharging cylinder section which are sequentially connected from top to bottom, wherein the diameter of the cylindrical feeding cylinder section is larger than that of the cylindrical discharging cylinder section.

More specifically, in the technical scheme, the plurality of upper stirring rods are corresponding to the conical middle charging barrel sections and are uniformly and spirally upwards distributed on the stirring columns, the tail end of each upper stirring rod is provided with a conical spring, and one end with a large diameter in the conical spring is in interference fit with the inner wall of the charging barrel; the lower stirring rods correspond to the cylindrical blanking barrel sections and are uniformly and spirally downwards distributed on the stirring columns.

Further specifically, in the above technical scheme, the first mechanism of breaking up include supporting beam, two gyro wheels and two step shaft, supporting beam set up in the bottom of spliced pole, two gyro wheels are adorned respectively at the both ends of supporting beam, and two gyro wheels erect on the feed cylinder section in the cone, two step shaft symmetry are established on supporting beam, the diameter of the upper portion axle section in every step shaft is greater than the diameter of lower part axle section, and all the cover is equipped with the hose on the lower part axle section in every step shaft, and the terminal of hose is laminated with the inner wall of stirring base.

Further specifically, in the above technical scheme, the second scattering mechanism comprises a small kidney-shaped ring and a large kidney-shaped ring, the small kidney-shaped ring is arranged at the front end of the powder discharging rod, the large kidney-shaped ring is arranged at the front end of the small kidney-shaped ring, and the large kidney-shaped ring is positioned in the powder discharging chute.

The beneficial effects of the invention are as follows: can effectively cope with various oily or high-viscosity powder, the powder is not easy to accumulate at a powder outlet, normal powder discharging is ensured, the powder discharging precision is ensured, and the powder discharging utilization rate of the powder is improved.

Drawings

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

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic exploded view of the present invention;

FIG. 3 is a schematic structural view of a stirrer;

FIG. 4 is a front view of FIG. 3;

FIG. 5 is a schematic structural view of a cartridge;

fig. 6 is a schematic diagram of the operation of the present invention.

The reference numerals in the figures are: 1. a cartridge cover; 2. a stirring motor; 3. a material cylinder cover fixing bracket; 4. an outer drive sleeve; 5. a motor mounting cover; 6. an inner cover of the material cover; 7. a stirrer; 8. a charging barrel; 9. a seal ring; 10. a stirring base; 11. a powder outlet chute; 12. a stirring spring; 13. a powder discharging rod; 14. a rear seat ring; 8-1, a cylindrical feeding cylinder section; 8-2, a conical middle charging barrel section; 8-3, a cylindrical blanking barrel section; 7-1, stirring the upright post; 7-2, upper stirring cross bars; 7-3, lower stirring cross bars; 7-4, conical springs; 7-5, supporting the cross beam; 7-6, idler wheels; 7-7, a stepped shaft.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the invention and therefore show only the structures which are relevant to the invention.

Referring to fig. 1 to 6, the powder discharging device for high-viscosity powder of the multifunctional beverage machine comprises a material cylinder cover 1, a stirring motor 2, a material cylinder cover fixing bracket 3, an outer driving sleeve 4, a motor mounting cover 5, a material cylinder cover inner cover 6, a stirrer 7, a material cylinder 8, a sealing ring 9, a stirring base 10, a powder discharging inclined channel 11, a stirring spring 12, a powder discharging rod 13 and a rear seat ring 14.

The motor mounting cover 5 is arranged above the material cover inner cover 6, the stirring motor 2 is arranged on the motor mounting cover 5, the outer transmission sleeve 4 is arranged on the output shaft of the stirring motor 2, the material cylinder cover 1 is arranged above the motor mounting cover 5, and the material cylinder cover fixing bracket 3 is arranged in the material cylinder cover 1 and is used for fixing the material cylinder cover 1 on the motor mounting cover 5; the sealing washer 9 is installed in the sealing washer mounting groove of feed cylinder 8, fills the clearance between feed cylinder 8 outer wall and the quick-witted case top feed cylinder mounting hole, prevents to have the powder unrestrained entering machine inside when dismantling clean agitator 7, and sealing washer 9 also plays certain cushioning effect simultaneously, reduces the noise that the powder discharging device during operation and machine production resonance sent. The stirrer 7 is arranged in the charging barrel 8, the stirring base 10 is arranged at the bottom of the charging barrel 8, and the powder outlet rod 13 is arranged in the stirring base 10 to play a role in conveying powder. A rear race 14 is mounted at the rear end of the mixing base 10 and serves to secure the powder discharge rod 13 within the mixing base 10, i.e., the rear race 14 serves to secure the powder discharge rod 13 against bouncing back and forth. The powder outlet chute 11 is arranged at the front end powder outlet of the stirring base 10, and the stirrer 7 and the powder outlet rod 13 rotate simultaneously to push out the powder in the charging barrel 8 and fall out through the powder outlet chute 11. The stirring spring 12 is arranged at the front end of the powder discharging rod 13, and when the powder discharging rod 13 rotates, the stirring spring 12 is driven to rotate together, and when the stirring motor 2 works, the powder discharging motor works to drive the powder discharging rod 13 to rotate anticlockwise so as to push out powder in the stirring base 10. The stirrer 7 rotates under the drive of the stirring motor 2 to convey the powder to the stirring base 10, so as to form the supply and demand balance of the powder. The stirring spring 12 breaks up the powder conveyed into the powder discharge chute 11, and prevents the powder from accumulating in the powder discharge chute 11. That is, when the powder discharging device performs the powder discharging operation, the powder discharging rod 13 rotates simultaneously with the stirrer 7, the powder discharging rod 13 plays a role of laterally pushing powder, the powder in the stirring base 10 is pushed out, and the powder falls out through the powder discharging chute 11, thereby completing the final powder discharging operation. The front end of the powder discharging rod 13 can scatter the powder entering the powder discharging chute 11, and the powder is prevented from being adhered and accumulated in the powder discharging chute 11 to influence the normal powder discharging and the powder discharging precision.

The stirring columns 7-1 of the stirrer 7 are densely provided with a plurality of stirring rods for uniformly scattering the powder in the feed cylinder 8, and the stirring rods comprise a plurality of upper stirring rods 7-2 which are positioned at the upper half part of the stirring columns 7-1 and used for supporting the powder in the feed cylinder 8, and a plurality of lower stirring rods 7-3 which are positioned at the lower half part of the stirring columns 7-1 and used for pushing the powder in the feed cylinder 8 downwards. Specifically, nine upper stirring crossbars 7-2 corresponding to the conical middle barrel section 8-2 are uniformly and spirally arranged upwards on the upper part of the stirring upright post 7-1 of the stirrer 7, and the distance between the top end of each upper stirring crossbar 7-2 and the barrel 8 is equal. The included angles between any two adjacent upper stirring crossbars 7-2 are equal and are 45 degrees. The spaces between any two adjacent upper stirring crossbars 7-2 are equal, and the spaces are 9mm. A conical spring 7-4 is arranged at the tail end of each upper stirring cross rod 7-2. The large-diameter end of the conical spring 7-4 is in interference fit with the inner wall of the charging barrel 8, and pretightening force is provided. When the stirrer 7 rotates anticlockwise, the nine upper stirring cross rods 7-2 form an upward pushing lifting force on the powder, the upward pushing force on the powder plays a role in supporting about 40% of the powder on the upper half part of the charging barrel 8, the gravity pressure on 60% of the powder on the lower part of the charging barrel 8 is effectively reduced, the density of about 60% of the powder on the lower part of the charging barrel 8 is ensured not to be greatly changed, and therefore the powder discharging precision is ensured. That is, the densely distributed stirring rods can effectively and uniformly break up the powder in the barrel 8 when the stirrer 7 rotates. The upper half part of the stirrer 7 plays a role in supporting powder on the upper half part in the charging barrel 8, so that the powder in the lower half part of the charging barrel 8 and the stirring base 10 is prevented from influencing the powder discharging precision due to the gradual increase of the density after being pressed by the gravity of the flour.

The bottom of the stirring column 7-1 is also provided with a first scattering mechanism for scattering the powder in the stirring base 10. The first scattering mechanism comprises a supporting beam 7-5, two idler wheels 7-6 and two stepped shafts 7-7, wherein the supporting beam 7-5 is arranged at the bottom of the stirring column 7-1, the two idler wheels 7-6 are respectively arranged at two ends of the supporting beam 7-5, the two idler wheels 7-6 are erected on a conical middle charging barrel section 8-2, the two stepped shafts 7-7 are symmetrically arranged on the supporting beam 7-5, the diameter of an upper shaft section in each stepped shaft 7-7 is larger than that of a lower shaft section, a hose is sleeved on the lower shaft section in each stepped shaft 7-7, and the tail end of the hose is attached to the inner wall of the stirring base 10.

The front end of the powder discharging rod 13 is also provided with a second scattering mechanism for scattering the powder in the powder discharging chute 11. The second scattering mechanism comprises a small kidney-shaped ring 13-1 and a large kidney-shaped ring 13-2, the small kidney-shaped ring 13-1 is arranged at the front end of the powder discharging rod 13, the large kidney-shaped ring 13-2 is arranged at the front end of the small kidney-shaped ring 13-1, and the large kidney-shaped ring 13-2 is positioned in the powder discharging chute 11.

The charging barrel 8 mainly comprises a cylindrical charging barrel section 8-1, a conical middle charging barrel section 8-2 and a cylindrical discharging barrel section 8-3 which are sequentially connected from top to bottom, wherein the diameter of the cylindrical charging barrel section 8-1 is larger than that of the cylindrical discharging barrel section 8-3. The powder feeding device is convenient for the powder feeding process without leakage, and the cylindrical feeding barrel section 8-1 and the conical middle barrel section 8-2 are exposed outside the machine, so that the use condition of the powder in the powder feeding barrel 8 can be intuitively reflected, and the phenomenon of material shortage is avoided. Compared with the traditional square material box, the cylindrical vertical material barrel 8 is regular and has no dead angle, the adaptive stirrer 7 is used for assisting in stopping the phenomenon that powder on the inner wall of the material barrel 8 is remained, and the utilization rate of the powder in the material barrel 8 is improved to the maximum extent.

The plurality of upper stirring rods 7-2 are corresponding to the conical middle charging barrel sections 8-2 and are uniformly and spirally upwards arranged on the stirring columns 7-1, the tail end of each upper stirring rod 7-2 is provided with a conical spring 7-4, and one end with a large diameter in the conical springs 7-4 is in interference fit with the inner wall of the charging barrel 8; the lower stirring rods 7-3 correspond to the cylindrical blanking barrel sections 8-3 and are uniformly and spirally arranged downwards on the stirring column 7-1. The conical spring 7-4 can scrape the powder on the inner wall of the blanking cylinder 8 when the stirrer 7 rotates. The conical spring 7-4 at the tail end of the upper stirring cross rod 7-2 scrapes off powder on the inner wall of the conical middle cylinder section 8-2 when rotating, so that powder accumulation is prevented, and the utilization rate of the powder is further improved.

Eleven lower stirring cross bars 7-3 corresponding to the cylindrical blanking barrel sections 8-3 are uniformly and spirally downwards arranged at the lower part of the stirring upright post 7-1, the distance between the top end of each lower stirring cross bar 7-3 and the blanking barrel section 8 is equal, and the included angle between any two adjacent lower stirring cross bars 7-3 is equal, and is 45 degrees. The spacing between any two adjacent lower stirring crossbars 7-3 is also equal, and the spacing is 9mm. When the stirrer 7 rotates anticlockwise, the eleven lower stirring cross bars 7-3 push the powder downwards while scattering the powder, and the powder pushed downwards and the powder discharge amount form supply-demand balance, so that the powder discharge precision is prevented from being influenced due to the lower density of the powder at the lower part of the charging barrel 8. That is, the lower part of the stirrer 7 plays a role in pushing down the powder in the cylinder 8, supplementing the powder reduced by the powder discharge, and forming a supply-demand balance between the powder supply and the powder discharge, preventing the powder density in the stirring base 10 from becoming small or hollow to affect the powder discharge accuracy or failing to discharge normally due to the powder supply smaller than the powder discharge.

The bottom of the stirring upright post 7-1 is provided with a supporting cross beam 7-5, both ends of the supporting cross beam 7-5 are provided with idler wheels 7-6, and the two idler wheels 7-6 are erected on the conical middle material barrel section 8-2 to play a role in positioning and supporting the stirrer 7. When the stirrer 7 rotates, rolling friction is formed between the idler wheel 7-6 and the conical middle barrel section 8-2, so that resistance applied to the rotation of the stirrer 7 is greatly reduced.

Two stepped shafts 7-7 are symmetrically arranged on the supporting beam 7-5, the diameter of the upper shaft section in each stepped shaft 7-7 is larger than that of the lower shaft section, the diameter of the upper shaft section is 13mm, the diameter of the lower shaft section is 4mm, hoses are sleeved on the lower shaft sections in each stepped shaft 7-7, the outer diameter of each hose is 8mm, the length of each hose is 25mm, and the tail ends of the hoses are attached to the inner wall of the stirring base 10. When the stirrer 7 rotates, the two stepped shafts 7-7 fully stir and scatter the powder at the bottom of the charging barrel 8, so that the powder in the stirring base 10 is prevented from being compacted, the powder on the inner wall of the stirring base 10 is scraped off by the hose, and the utilization rate of the powder in the charging barrel 8 is improved. That is, when the stirrer 7 rotates, the powder in the stirring base can be effectively scattered at the tail end of the stirrer, so that the powder is prevented from being bonded into a block in the stirring base 10 or the powder in the stirring base 10 is compacted due to the downward pushing acting force applied to the powder by the stirrer 7, and the powder discharging precision is further ensured.

With the above-described preferred embodiments according to the present invention as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present invention. The technical scope of the present invention is not limited to the description, but must be determined as the scope of the claims.

Claims

1. Powder discharging device for high-viscosity powder of multifunctional beverage machine, which is characterized in that: the powder discharge chute (11) is arranged at the front end of the stirring base (10), the stirrer (7) and the powder discharge rod (13) rotate simultaneously to push out powder in the charging barrel (8) and discharge the powder through the powder discharge chute (11); a plurality of stirring rods for uniformly scattering the powder in the feed cylinder (8) are densely distributed on the stirring column (7-1) of the stirrer (7), and each stirring rod comprises a plurality of upper stirring rods (7-2) which are positioned on the upper half part of the stirring column (7-1) and used for supporting the powder in the feed cylinder (8) and a plurality of lower stirring rods (7-3) which are positioned on the lower half part of the stirring column (7-1) and used for pushing the powder in the feed cylinder (8) downwards; the bottom of the stirring column (7-1) is also provided with a first scattering mechanism for scattering powder in the stirring base (10); the scattering mechanism I comprises a supporting beam (7-5), two rollers (7-6) and two stepped shafts (7-7), wherein the supporting beam (7-5) is arranged at the bottom of a stirring column (7-1), the two rollers (7-6) are respectively arranged at two ends of the supporting beam (7-5), the two rollers (7-6) are erected on a conical middle charging barrel section (8-2), the two stepped shafts (7-7) are symmetrically arranged on the supporting beam (7-5), the diameter of the upper shaft section in each stepped shaft (7-7) is larger than that of the lower shaft section, a hose is sleeved on the lower shaft section in each stepped shaft (7-7), and the tail end of the hose is attached to the inner wall of a stirring base (10);

the upper stirring rods (7-2) are uniformly and spirally upwards arranged on the stirring column (7-1), and the lower stirring rods (7-3) are uniformly and spirally downwards arranged on the stirring column (7-1).

2. The powder discharging device for high-viscosity powder of a multifunctional beverage machine according to claim 1, wherein: the front end of the powder discharging rod (13) is also provided with a second scattering mechanism for scattering powder in the powder discharging chute (11).

3. The powder discharging device for high-viscosity powder of a multifunctional beverage machine according to claim 1, wherein: the charging barrel (8) mainly comprises a cylindrical charging barrel section (8-1), a conical middle charging barrel section (8-2) and a cylindrical discharging barrel section (8-3) which are sequentially connected from top to bottom, wherein the diameter of the cylindrical charging barrel section (8-1) is larger than that of the cylindrical discharging barrel section (8-3).

4. A powder discharge device for high viscosity powder of a multi-functional beverage machine according to claim 3, wherein: the upper stirring rods (7-2) correspond to the conical middle charging barrel sections (8-2), conical springs (7-4) are arranged at the tail ends of the upper stirring rods (7-2), and one large-diameter end of each conical spring (7-4) is in interference fit with the inner wall of the charging barrel (8); the lower stirring rods (7-3) correspond to the cylindrical blanking barrel sections (8-3).

5. The powder discharging device for high-viscosity powder of a multifunctional beverage machine according to claim 2, wherein: the second scattering mechanism comprises a small kidney-shaped ring (13-1) and a large kidney-shaped ring (13-2), the small kidney-shaped ring (13-1) is arranged at the front end of the powder discharging rod (13), the large kidney-shaped ring (13-2) is arranged at the front end of the small kidney-shaped ring (13-1), and the large kidney-shaped ring (13-2) is located in the powder discharging chute (11).