CN212768684U - Nano material charging equipment - Google Patents

Abstract

The utility model discloses a nano-material feeding equipment relates to nano-material technical field, for solving current nanometer powder and agglomerating easily and gathering together, the unloading degree of consistency is relatively poor, leads to the lower problem of reinforced quality. The below of storage tank is provided with the dispersion tank, the below of dispersion tank is provided with screw conveyor, the upper end of dispersion tank is provided with servo motor, servo motor's lower extreme is provided with the main shaft, and the main shaft is located the inside of dispersion tank, the outside of main shaft is provided with helical blade and dispersion blade, and helical blade is located dispersion blade's below, and dispersion blade is provided with five, the inside both sides of storage tank all are provided with the fixture block, the one end of fixture block is provided with the baffle, and the baffle passes through spacing pivot with the fixture block to be connected, be provided with the elastic component between baffle and the storage tank, and elastic component and baffle and the equal fixed connection of storage tank.

Description

Nano material charging equipment

Technical Field

The utility model relates to a nano-material technical field specifically is a nano-material charging equipment.

Background

The three major industries of development of the economy of this century are the information science and technology, the life science and technology, and the nano science and technology. Nanotechnology is a firm foundation for further development of information and life science technologies. The nano-grade structure material is a general name of hyperfine particle materials with at least one dimension in a nano-scale range in a three-dimensional space, and is a powdery, lumpy natural or artificial material consisting of basic particles.

However, the existing nano powder is easy to agglomerate and gather together, the blanking uniformity is poor, the feeding quality is low, the existing requirements are not met, and the nano material feeding equipment is provided for the situation.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a nano-material charging equipment to current nanometer powder that proposes in solving above-mentioned background art is easy to agglomerate and is gathered together, and the unloading degree of consistency is relatively poor, leads to the lower problem of reinforced quality.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a nano-material charging equipment, includes the storage tank, the below of storage tank is provided with the dispersion jar, the below of dispersion jar is provided with screw conveyor, the upper end of dispersion jar is provided with servo motor, servo motor's lower extreme is provided with the main shaft, and the main shaft is located the inside of dispersion jar, the outside of main shaft is provided with helical blade and dispersion blade, and helical blade is located the below of dispersion blade, and the dispersion blade is provided with five.

Preferably, the inside both sides of storage tank all are provided with the fixture block, the one end of fixture block is provided with the baffle, and the baffle is connected through spacing pivot with the fixture block, be provided with the elastic component between baffle and the storage tank, and the elastic component and the equal fixed connection of baffle and storage tank.

Preferably, a first material conveying pipe is arranged between the material storage tank and the dispersing tank, and a second material conveying pipe is arranged between the dispersing tank and the spiral conveying mechanism.

Preferably, the second conveying pipeline and the first conveying pipeline are both provided with valves, and the valves are connected with the second conveying pipeline and the first conveying pipeline through flanges.

Preferably, the spiral conveying mechanism comprises a spiral conveying rod and a driving motor, the driving motor is located outside the spiral conveying mechanism, the spiral conveying rod is located inside the spiral conveying mechanism and connected with the driving motor through a coupler, and a corrugated discharging hose is arranged on one side of the lower end of the spiral conveying mechanism.

Preferably, the front ends of the material storage tank and the dispersion tank are provided with sight holes.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses an add the dispersion jar between storage tank and screw conveyor, play the effect of transition, when the nanometer powder got into the dispersion jar, servo motor work drove the main shaft and rotates, and the main shaft drives its outside helical blade and dispersion blade and rotates in step, disperses the shearing to the nanometer powder that gets into, avoids nanometer powder to conglomerate together, degree of consistency and dispersion degree when improving nanometer powder unloading to improve reinforced quality.

2. The utility model discloses a driving motor work drives the auger delivery pole and rotates the realization to the transport of nanometer powder, through the rotation number of turns in adjusting driving motor unit interval, can adjust the feeding volume in the unit interval to improve reinforced precision.

3. The utility model discloses a baffle can rotate for the fixture block, and when feeding material to the storage tank, the baffle is pressed and is rotated along the fixture block, and the elastic component is elongated, and two baffles are the open mode, and after the feeding material, the baffle does not receive exogenic action, and the elastic component relies on self elasticity to drive the baffle and resets, and two baffles are the closure state this moment, have avoided external impurity to get into the inside of storage tank, avoid the nanometer powder to receive the pollution to further improve reinforced quality.

Drawings

Fig. 1 is a schematic structural diagram of a nano-material feeding device of the present invention;

FIG. 2 is a schematic structural view of the storage tank of the present invention;

fig. 3 is a schematic structural diagram of the dispersion tank of the present invention.

In the figure: 1. a material storage tank; 2. a dispersion tank; 3. a screw conveying mechanism; 4. a servo motor; 5. a main shaft; 6. a helical blade; 7. dispersing the leaves; 8. a clamping block; 9. a baffle plate; 10. an elastic member; 11. a first feed delivery pipe; 12. a second delivery pipe; 13. a valve; 14. a screw conveying rod; 15. a drive motor; 16. a corrugated discharge hose; 17. and (6) a sight hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, the present invention provides an embodiment: a nano material feeding device comprises a material storage tank 1, a dispersion tank 2 is arranged below the material storage tank 1, a spiral conveying mechanism 3 is arranged below the dispersion tank 2, a servo motor 4 is arranged at the upper end of the dispersion tank 2, a main shaft 5 is arranged at the lower end of the servo motor 4, and the main shaft 5 is positioned inside the dispersion tank 2, the outer part of the main shaft 5 is provided with a helical blade 6 and a dispersion blade 7, and the helical blades 6 are positioned below the dispersing blades 7, and five dispersing blades 7 are arranged, the dispersing tank 2 plays a transitional role, when the nano powder enters the dispersing tank 2, the servo motor 4 works to drive the main shaft 5 to rotate, the main shaft 5 drives the helical blade 6 and the dispersing blade 7 outside the main shaft to synchronously rotate, the nano powder entering the dispersing tank 2 is dispersed and sheared, so that the nano powder is prevented from being agglomerated together, and the uniformity and the dispersity of the nano powder during blanking are improved.

Further, the inside both sides of storage tank 1 all are provided with fixture block 8, the one end of fixture block 8 is provided with baffle 9, and baffle 9 is connected through spacing pivot with fixture block 8, be provided with elastic component 10 between baffle 9 and the storage tank 1, and elastic component 10 and the equal fixed connection of baffle 9 and storage tank 1, when needs carry out the feed supplement to storage tank 1, the nanometer powder whereabouts, baffle 9 is pressed and is rotated along fixture block 8, elastic component 10 is elongated, two baffles 9 are the open mode this moment, the nanometer powder gets into the inside of storage tank 1, after the feed supplement, baffle 9 does not receive the exogenic action, elastic component 10 relies on self elasticity to drive baffle 9 and resets, two baffles 9 are the closed mode this moment, avoided external impurity to get into the inside of storage tank 1, avoid the nanometer powder to receive the pollution, thereby further improve reinforced quality.

Further, a first material conveying pipe 11 is arranged between the material storage tank 1 and the dispersing tank 2, a second material conveying pipe 12 is arranged between the dispersing tank 2 and the spiral conveying mechanism 3, and the nano powder in the material storage tank 1 after opening the valve 13 enters the dispersing tank 2 through the first material conveying pipe 11, is dispersed in the dispersing tank 2, and then enters the spiral conveying mechanism 3 through the second material conveying pipe 12.

Further, valves 13 are arranged outside the second material conveying pipe 12 and the first material conveying pipe 11, and the valves 13 are connected with the second material conveying pipe 12 and the first material conveying pipe 11 through flanges, so that the blanking speed can be controlled.

Further, screw conveying mechanism 3 includes screw conveying rod 14 and driving motor 15, and driving motor 15 is located screw conveying mechanism 3's outside, and screw conveying rod 14 is located screw conveying mechanism 3's inside, and screw conveying rod 14 passes through the coupling joint with driving motor 15, one side of 3 lower extremes of screw conveying mechanism is provided with ripple discharging hose 16, driving motor 15 work drives screw conveying rod 14 and rotates and can realize the transport to the nanometer powder, through the number of turns of rotation in adjusting driving motor 15 unit interval, can adjust the feeding amount in the unit interval, thereby improve reinforced precision.

Further, the front end of storage tank 1 and dispersion tank 2 all is provided with looks hole 17, conveniently observes storage tank 1 and dispersion tank 2.

The working principle is as follows: when the nanometer powder feeding device is used, the nanometer powder inside the material storage tank 1 of the valve 13 is opened and enters the inside of the dispersion tank 2 through the first material conveying pipe 11, when the nanometer powder enters the dispersion tank 2, the servo motor 4 works to drive the spindle 5 to rotate, the spindle 5 drives the helical blade 6 and the dispersion blade 7 outside the spindle 5 to synchronously rotate, the nanometer powder entering the dispersion tank 2 is dispersed and sheared, the nanometer powder is prevented from being agglomerated together, the uniformity and the dispersion degree of the nanometer powder during the feeding process are improved, the dispersed nanometer powder enters the inside of the spiral conveying mechanism 3 through the second material conveying pipe 12, the driving motor 15 works to drive the spiral conveying rod 14 to rotate, the nanometer powder can be conveyed, the feeding amount in unit time can be adjusted through adjusting the number of rotation turns of the driving motor 15 in unit time, the feeding accuracy is improved, because the baffle plate 9 can rotate relative to the clamping block 8, when needs carry out the feed supplement to storage tank 1, the nanometer powder whereabouts, baffle 9 is pressed and is rotated along fixture block 8, elastic component 10 is elongated, two baffles 9 are the open mode this moment, the nanometer powder gets into storage tank 1's inside, after the feed supplement, baffle 9 does not receive exogenic action, elastic component 10 relies on self elasticity to drive baffle 9 and resets, two baffles 9 are the closure state this moment, avoided external impurity to get into storage tank 1's inside, avoid the nanometer powder to receive the pollution, thereby further improve feeding quality.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides a nano-material charging equipment, includes storage tank (1), its characterized in that: the utility model discloses a dispersion tank, including storage tank (1), dispersion tank (2), screw conveyor (3) are provided with to the below of storage tank (1), the upper end of dispersion tank (2) is provided with servo motor (4), the lower extreme of servo motor (4) is provided with main shaft (5), and main shaft (5) are located the inside of dispersion tank (2), the outside of main shaft (5) is provided with helical blade (6) and dispersion blade (7), and helical blade (6) are located the below of dispersion blade (7), and dispersion blade (7) are provided with five.

2. The nanomaterial feeding apparatus according to claim 1, wherein: the novel storage tank is characterized in that clamping blocks (8) are arranged on two sides of the interior of the storage tank (1), a baffle (9) is arranged at one end of each clamping block (8), the baffle (9) is connected with the corresponding clamping block (8) through a limiting rotating shaft, an elastic piece (10) is arranged between the baffle (9) and the storage tank (1), and the elastic piece (10) is fixedly connected with the baffle (9) and the storage tank (1).

3. The nanomaterial feeding apparatus according to claim 1, wherein: a first material conveying pipe (11) is arranged between the material storage tank (1) and the dispersion tank (2), and a second material conveying pipe (12) is arranged between the dispersion tank (2) and the spiral conveying mechanism (3).

4. The nanomaterial feeding apparatus according to claim 3, wherein: and valves (13) are arranged outside the second material conveying pipe (12) and the first material conveying pipe (11), and the valves (13) are connected with the second material conveying pipe (12) and the first material conveying pipe (11) through flanges.

5. The nanomaterial feeding apparatus according to claim 1, wherein: spiral conveying mechanism (3) include spiral conveying rod (14) and driving motor (15), and driving motor (15) are located the outside of spiral conveying mechanism (3), and spiral conveying rod (14) are located the inside of spiral conveying mechanism (3), and spiral conveying rod (14) pass through the coupling joint with driving motor (15), one side of spiral conveying mechanism (3) lower extreme is provided with ripple discharging hose (16).

6. The nanomaterial feeding apparatus according to claim 1, wherein: the front ends of the material storage tank (1) and the dispersion tank (2) are provided with sight holes (17).

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