CN219849008U - Prevent grain powder separation unloading structure - Google Patents

Abstract

The utility model discloses a granule powder separation and blanking structure, and aims to solve the defect that granule powder separation is caused by linkage of the stirring speed and the blanking speed of a granule powder blanking device and incapability of being controlled independently. The utility model comprises a hopper for loading materials; the stirring shaft rotates to stir and mix materials in the hopper; the feeding shaft rotates to convey materials falling from the hopper outwards; the stirring shaft and the feeding shaft are respectively connected with two independent drivers, and the two drivers respectively drive the stirring shaft and the feeding shaft to rotate. The stirring speed of the stirring shaft is not limited and influenced by the rotating speed of the feeding shaft, so that the phenomenon of particle-powder separation is avoided under the condition of normal discharging, and the particles and the powder are uniformly mixed.

Description

Prevent grain powder separation unloading structure

Technical Field

The utility model relates to melt extrusion production equipment, in particular to a blanking structure capable of preventing particle and powder separation.

Background

At present, in the material blanking process of melt extrusion production, in order to prevent powder fixation, the material is generally required to be stirred, and the stirring speed is generally linked with the blanking speed and cannot be controlled independently. And the particle and powder are mixed and then are subjected to transitional stirring, so that the particle and the powder are separated. After the powder is separated, the premixing effect is greatly reduced, and the components in the final product are unevenly distributed.

Disclosure of Invention

In order to overcome the defects, the utility model provides a granule and powder separation-preventing blanking structure, which can prevent granule and powder from being separated under the condition of normal blanking and is uniform in granule and powder mixing.

In order to solve the technical problems, the utility model adopts the following technical scheme: prevent grain powder separation unloading structure includes:

a hopper for loading material;

the stirring shaft rotates to stir and mix materials in the hopper;

the feeding shaft rotates to convey materials falling from the hopper outwards;

the stirring shaft and the feeding shaft are respectively connected with two independent drivers, and the two drivers respectively drive the stirring shaft and the feeding shaft to rotate.

During blanking, the premixed granules and powder are poured into a hopper, and the materials can be smoothly blanked under the condition that the granule and powder separation does not occur by adjusting the stirring speed of a stirring shaft, and meanwhile, the bridging phenomenon does not occur. The utility model has good practicability when the materials to be mixed are fed. The two independent drivers respectively drive the stirring shaft and the feeding shaft to rotate, that is to say, the stirring shaft and the feeding shaft are independently controlled, so that the stirring speed of the stirring shaft is not limited and influenced by the rotating speed of the feeding shaft, and the phenomenon of particle-powder separation is avoided under the condition of normal discharging, and the particles and the powder are uniformly mixed.

Preferably, the stirring shaft is transversely arranged, a C-shaped stirring rod is connected to the stirring shaft, and two ends of the stirring rod are connected with the stirring shaft. The stirring rod of C shape is effectual to the stirring of material, and the material is difficult for gluing on the stirring rod surface.

Preferably, a bin is arranged at the lower end of the hopper, and the stirring shaft is arranged in the bin. The setting of feed bin is convenient for the whereabouts of material.

Preferably, a moisture-proof cover is arranged at the upper end of the hopper. The dampproof cover covers the upper end of the hopper, and can prevent wind and moisture from affecting materials.

Preferably, a transparent visual window is arranged on the side wall of the hopper. The setting of visual window is convenient for observe the quantity and the whereabouts speed of hopper interior material.

Preferably, a feeding pipe is arranged below the hopper, a feeding screw is arranged in the feeding pipe, and a feeding shaft is in transmission connection with the feeding screw. The feeding screw and the feeding shaft rotate together to enable the materials to be conveyed along the feeding pipe.

Preferably, one end of the feeding pipe is connected with a vertical discharging cylinder, and a transparent observation window is arranged on the side wall of the discharging cylinder. The setting of ejection of compact section of thick bamboo is convenient for the output of material, and the observation window is convenient for observe the ejection of compact speed of material.

Preferably, two feeding screws are arranged in the feeding pipe to form a double-screw conveying mechanism. The feeding speed of the double-screw conveying mechanism is stable and reliable, and the uniform mixing of materials is facilitated.

Preferably, the driver for driving the stirring shaft to rotate comprises a stirring motor and a speed reducer, wherein an output shaft of the stirring motor is connected with an input end of the speed reducer, and a stirring gear set is connected between an output end of the speed reducer and the stirring shaft in a transmission manner. After the stirring motor runs and is decelerated through the speed reducer, power is transmitted to the stirring shaft through the stirring gear set to run, and the stirring motor is stable and reliable. The stirring speed of the stirring shaft is regulated by regulating the rotating speed of the stirring motor.

Preferably, the driver for driving the feeding shaft to rotate comprises a feeding motor and a speed reducer, wherein an output shaft of the feeding motor is connected with an input end of the speed reducer, and a feeding gear set is connected between an output end of the speed reducer and the feeding shaft in a transmission manner. After the feeding motor runs and is decelerated by the speed reducer, power is transmitted to the feeding shaft to run through the feeding gear set, and the feeding motor is stable and reliable. The rotating speed of the feeding shaft is adjusted by adjusting the rotating speed of the feeding motor, so that the discharging speed is adjusted.

Compared with the prior art, the utility model has the beneficial effects that: the particle powder separation unloading structure of preventing of this patent can guarantee under the condition of normal unloading, avoids appearing the phenomenon of particle powder separation, and particle powder misce bene.

Drawings

FIG. 1 is a schematic view of a construction of the present utility model;

FIG. 2 is a left side view of the present utility model;

FIG. 3 is a right side view of the present utility model;

FIG. 4 is a schematic view of the internal structure of the hopper of the present utility model;

in the figure: 1. hopper, 2, the guide surface, 3, dampproof cover, 4, the (mixing) shaft, 5, the pay-off axle, 6, puddler, 7, feed bin, 8, visual window, 9, the feed tube, 10, ejection of compact section of thick bamboo, 11, observation window, 12, bottom plate, 13, mount pad, 14, agitator motor, 15, reduction gear, 16, driving gear, 17, transition gear, 18, driven gear, 19, the pay-off motor, 20, the speed reducer, 21, first gear, 22, second gear.

Detailed Description

The technical scheme of the utility model is further specifically described by the following specific embodiments with reference to the accompanying drawings:

examples: an anti-particle-powder separation blanking structure (see fig. 1 to 4) comprises:

a hopper 1 for loading materials; one side of the hopper is provided with an inclined material guiding surface 2; the upper end of the hopper is provided with a moisture-proof cover 3;

the stirring shaft 4 rotates to stir and mix the materials in the hopper;

a feeding shaft 5 which rotates to convey the material falling from the hopper outwards;

the stirring shaft and the feeding shaft are respectively connected with two independent drivers, and the two drivers respectively drive the stirring shaft and the feeding shaft to rotate.

The stirring shaft is transversely arranged, a C-shaped stirring rod 6 is connected to the stirring shaft, and two ends of the stirring rod are connected with the stirring shaft. Two stirring rods are symmetrically arranged. The stirring rod surface is smooth, prevents that the material from sticking on the stirring rod surface. The lower end of the hopper is provided with a feed bin 7, and the stirring shaft is arranged in the feed bin. The side wall of the hopper is provided with a transparent visual window 8.

A feeding pipe 9 is arranged below the hopper, the feeding pipe is transversely arranged, a feeding hole is formed in the feeding pipe, and the feeding hole is correspondingly connected with an opening at the lower end of the storage bin. The feeding pipe is internally provided with a feeding screw, and the feeding shaft is in transmission connection with the feeding screw. Two feeding screws are arranged in the feeding pipe to form a double-screw conveying mechanism. The feeding shaft drives the two feeding screws to rotate in the same direction to convey materials. One of belt transmission, chain transmission and gear transmission is arranged between the feeding shaft and the feeding screw. One end of the feeding pipe is connected with a vertical discharging cylinder 10, a transparent observation window 11 is arranged on the side wall of the discharging cylinder, and a cover plate is arranged at the upper end of the discharging cylinder.

A bottom plate 12 is arranged below the storage bin, and a feeding pipe is arranged on the bottom plate. The hopper is externally provided with a mounting seat 13, and both drivers are mounted on the mounting seat. The driver for driving the stirring shaft to rotate comprises a stirring motor 14 and a speed reducer 15, wherein an output shaft of the stirring motor is connected with an input end of the speed reducer, and a stirring gear set is connected between an output end of the speed reducer and the stirring shaft in a transmission manner. One end of the stirring shaft extends outwards and is arranged in the mounting seat, the stirring gear set comprises a driving gear 16, a transition gear 17 and a driven gear 18, the transition gear is rotatably arranged on the mounting seat, the driving gear is arranged on the output shaft of the speed reducer, the driven gear is arranged on the stirring shaft, and the transition gear is meshed and driven between the driving gear and the driven gear.

The driver for driving the feeding shaft to rotate comprises a feeding motor 19 and a speed reducer 20, wherein an output shaft of the feeding motor is connected with an input end of the speed reducer, and a feeding gear set is connected between an output end of the speed reducer and the feeding shaft in a transmission manner. The feeding gear set comprises a first gear 21 and a second gear 22, the first gear is arranged on the output shaft of the speed reducer, the second gear is arranged on the feeding shaft, and the first gear and the second gear are meshed for transmission.

During blanking, the premixed granules and powder are poured into a hopper, and the materials can be smoothly blanked under the condition that the granule and powder separation does not occur by adjusting the stirring speed of a stirring shaft, and meanwhile, the bridging phenomenon does not occur. The utility model has good practicability when the materials to be mixed are fed. The two independent drivers respectively drive the stirring shaft and the feeding shaft to rotate, that is to say, the stirring shaft and the feeding shaft are independently controlled, so that the stirring speed of the stirring shaft is not limited and influenced by the rotating speed of the feeding shaft, and the phenomenon of particle-powder separation is avoided under the condition of normal discharging, and the particles and the powder are uniformly mixed.

The above-described embodiments are merely preferred embodiments of the present utility model, and the present utility model is not limited in any way, and other variations and modifications may be made without departing from the technical aspects set forth in the claims.

Claims (5)

1. Prevent grain powder separation unloading structure, characterized by includes:

a hopper for loading material;

the stirring shaft rotates to stir and mix materials in the hopper;

the feeding shaft rotates to convey materials falling from the hopper outwards;

the stirring shaft and the feeding shaft are respectively connected with two independent drivers, and the two drivers respectively drive the stirring shaft and the feeding shaft to rotate; the stirring shaft is transversely arranged, a C-shaped stirring rod is connected to the stirring shaft, and two ends of the stirring rod are connected with the stirring shaft; the driver for driving the stirring shaft to rotate comprises a stirring motor and a speed reducer, wherein an output shaft of the stirring motor is connected with an input end of the speed reducer, and a stirring gear set is in transmission connection between the output end of the speed reducer and the stirring shaft; the stirring gear set comprises a driving gear, a transition gear and a driven gear, the driving gear is arranged on an output shaft of the speed reducer, the driven gear is arranged on the stirring shaft, and the transition gear is meshed and transmitted between the driving gear and the driven gear; the surface of the stirring rod is smooth; a transparent visual window is arranged on the side wall of the hopper; a feeding pipe is arranged below the hopper, a feeding screw is arranged in the feeding pipe, and a feeding shaft is in transmission connection with the feeding screw; two feeding screws are arranged in the feeding pipe to form a double-screw conveying mechanism.

2. The granule and powder separation preventing discharging structure according to claim 1, wherein a bin is arranged at the lower end of the hopper, and the stirring shaft is arranged in the bin.

3. The granule and powder separation preventing discharging structure according to claim 1, wherein a moisture-proof cover is arranged at the upper end of the hopper.

4. The granule and powder separation preventing discharging structure according to claim 1, wherein one end of the feeding pipe is connected with a vertical discharging barrel, and a transparent observation window is arranged on the side wall of the discharging barrel.

5. The granule and powder separation preventing discharging structure according to any one of claims 1 to 4, wherein the driver for driving the feeding shaft to rotate comprises a feeding motor and a speed reducer, an output shaft of the feeding motor is connected with an input end of the speed reducer, and a feeding gear set is in transmission connection between an output end of the speed reducer and the feeding shaft.