CN111939793A - Anti-adhesion mixing device and mixing method for metal blanks of 3D printer - Google Patents

Abstract

The invention discloses an anti-sticking 3D printer metal blank mixing device and a mixing method, and the device comprises a stirring box, a motor, a filter plate, a discharge hole and a top column, wherein a storage box is welded and fixed above the stirring box, the top end of the storage box is provided with a feed inlet, the bottom end of the storage box is provided with a discharge hole, a baffle is arranged in the discharge hole, the motor is fixed on the storage box through bolts, the tail end of an output shaft of the motor is fixed with a driving gear, the driving gear is mutually connected with a driven gear, the driven gear is fixed on a rotating shaft, the discharge hole is formed in the bottom end of the stirring box, the discharge hole is mutually connected with the cover plate, and the top column is. This antiseized knot 3D printer metal blank compounding device adopts adjustable discharge gate to control different metal material, makes its mixing ratio can control, can mix the stirring to metal powder through the stirring board, and the filtration pore of seting up on the stirring board can break up the metal powder of caking, prevents to bond together.

Description

Anti-adhesion mixing device and mixing method for metal blanks of 3D printer

Technical Field

The invention relates to the technical field of 3D printers, in particular to an anti-sticking 3D printer metal blank mixing device and a mixing method.

Background

The 3D printing is that related models are manufactured through a computer, and the manufactured models are printed through a 3D printer, so that the physical properties of the designed models can be detected quickly, the development time and the development cost of a large number of molds are saved, and the development of design is promoted.

Along with the high development of 3D technique, people are also more and more to the application demand of 3D technique, and common 3D printing consumables divide into soft and rigid material, and the consumables commonly used in the industry are metal powder, mixes different metal powder, is used for the 3D printer at last, but traditional metal powder compounding device has the compounding inhomogeneous, and simple structure sieves incomplete scheduling problem and causes certain damage to the instrument, so the urgent need is improved to above-mentioned traditional compounding device.

Disclosure of Invention

The invention aims to provide an anti-sticking 3D printer metal blank mixing device and a mixing method, and aims to solve the problems of uneven mixing, simple structure and incomplete screening in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an anti-sticking 3D printer metal blank mixing device comprises a stirring box, a motor, a filter plate, a discharge hole and a top column, wherein a storage box is fixedly welded above the stirring box, a feed inlet is formed in the top end of the storage box, a discharge outlet is formed in the bottom end of the storage box, a baffle plate is arranged in the discharge outlet, a scale plate is fixed on the baffle plate and is connected with a sliding gear, the sliding gear is fixed on the top end of the stirring box, the motor is fixed on the storage box through bolts, a driving gear is fixed at the tail end of an output shaft of the motor and is connected with a driven gear, the driven gear is fixed on a rotating shaft, a rotating shaft bearing is fixed at the bottom end of the storage box, the rotating shaft penetrates through the bottom plate of the storage box, stirring plates are uniformly distributed on two sides of the rotating shaft, filtering holes are distributed, and the storing groove has been seted up to the filter both sides to filter and spring interconnect, the other end of spring is fixed on the agitator tank simultaneously, the bin outlet is seted up in the agitator tank bottom, and bin outlet and apron interconnect to the apron is fixed on the agitator tank, the fore-set is fixed on the stirring board.

Preferably, the storage tanks are symmetrically distributed about the stirring tank, and the storage tanks are in a conical structure.

Preferably, the baffle is in meshed connection with the sliding gear, the area of the baffle is larger than that of the discharge hole, and the baffle is of an L-shaped structure.

Preferably, the driving gear is in meshed connection with the driven gear, and the diameter of the driving gear is larger than that of the driven gear.

Preferably, the filter plate, the discharge opening and the cover plate are distributed from top to bottom, and the area of the filter plate is larger than that of the discharge opening.

Preferably, the top columns are vertically distributed with the rotating plane of the stirring plate, and the height of the top columns is smaller than the distance from the bottom plane of the stirring plate at the lowest end to the upper plane of the bulge at the bottom end of the stirring box.

Compared with the prior art, the invention has the beneficial effects that: this antiseized knot 3D printer metal blank compounding device adopts adjustable discharge gate to control different metal material, makes its mixing ratio can control, can mix the stirring to metal powder through the stirring board, and the filtration pore of seting up on the stirring board can break up the metal powder of caking, prevents to bond together.

The size of different discharge gates is adjusted according to the ratio data control baffle of different metal powder, and accurate control discharge gate size ratio is come through the scale plate on the baffle, makes the size ratio of discharge gate the same with metal ratio data to reach accurate control compounding ratio.

Through the stirring structure that motor, driving gear, driven gear, rotation axis and stirring board are constituteed, guarantee that different metal powder can mix abundant assurance, the filtration pore of seting up on the stirring board can be the guarantee that prevents the powder caking.

Drawings

FIG. 1 is a schematic structural view of a front cross section of a stirring tank according to the present invention;

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

FIG. 3 is a front view of the filter plate of the present invention;

FIG. 4 is a schematic top view of a filter plate according to the present invention;

fig. 5 is a schematic view showing the state structure of the shutter and the slide gear in the present invention.

In the figure: 1. a stirring box; 2. a material storage box; 3. a feed inlet; 4. a discharge port; 5. a baffle plate; 6. a scale plate; 7. a sliding gear; 8. a motor; 9. a driving gear; 10. a driven gear; 11. a rotating shaft; 12. a stirring plate; 13. filtering holes; 14. a filter plate; 15. a storage tank; 16. a spring; 17. a discharge outlet; 18. a cover plate; 19. and (4) a top pillar.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an anti-adhesion 3D printer metal blank mixing device comprises a stirring box 1, a storage box 2, a feeding hole 3, a discharging hole 4, a baffle plate 5, a scale plate 6, a sliding gear 7, a motor 8, a driving gear 9, a driven gear 10, a rotating shaft 11, a stirring plate 12, a filtering hole 13, a filtering plate 14, a storage groove 15, a spring 16, a discharging hole 17, a cover plate 18 and a top column 19, wherein the storage box 2 is fixedly welded above the stirring box 1, the top end of the storage box 2 is provided with the feeding hole 3, the bottom end of the storage box 2 is provided with the discharging hole 4, the baffle plate 5 is arranged in the discharging hole 4, the scale plate 6 is fixed on the baffle plate 5, the baffle plate 5 is mutually connected with the sliding gear 7, the sliding gear 7 is fixed at the top end of the stirring box 1, the motor 8 is fixed on the storage box 2 through bolts, the tail end of an output shaft of the motor, driven gear 10 is fixed on rotation axis 11 simultaneously, rotation axis 11 bearing is fixed in 2 bottoms of stock box, and rotation axis 11 runs through 2 bottom plates of stock box, and 11 both sides evenly distributed of rotation axis have stirring board 12, it has filtration pore 13 to distribute on 12 to stir the board simultaneously, filter 14 sets up at 1 lower extreme of agitator tank, and storage tank 15 has been seted up to filter 14 both sides, and filter 14 and spring 16 interconnect, simultaneously spring 16's the other end is fixed on agitator tank 1, bin outlet 17 is seted up in 1 bottom of agitator tank, and bin outlet 17 and apron 18 interconnect, and apron 18 is fixed on agitator tank 1, fore-set 19 is fixed on stirring board 12.

The material storage boxes 2 are symmetrically distributed about the stirring box 1, and the material storage boxes 2 are of a conical structure, so that the metal blanks can smoothly slide down to the material outlet 4.

Baffle 5 is connected for the meshing with sliding gear 7, and the area of baffle 5 is greater than the area of discharge gate 4 to baffle 5 is "L" type structure, guarantees that baffle 5 can control the size of discharge gate 4.

The driving gear 9 is connected with the driven gear 10 in a meshed mode, the diameter of the driving gear 9 is larger than that of the driven gear 10, the power foundation of the whole device is achieved, and the stirring plate 12 can stably run.

The filter plate 14, the discharge opening 17 and the cover plate 18 are distributed from top to bottom, and the area of the filter plate 14 is larger than that of the discharge opening 17, so that the quality of the mixed powder discharged from the discharge opening 17 is guaranteed.

The top pillars 19 and the rotation plane of the stirring plate 12 are vertically distributed, and the height of the top pillars 19 is smaller than the distance from the bottom plane of the lowest stirring plate 12 to the upper plane of the bottom protrusion of the stirring box 1, which is the basis of the stable vibration of the filtering plate 14.

A material mixing method of an anti-sticking 3D printer metal blank material mixing device comprises the following steps: firstly, pouring different metal blank powders into different storage boxes 2, adjusting a baffle 5 according to the proportion of metal ingredients, adjusting the opening size proportion of a discharge port 4 through a scale plate 6 on the baffle 5 to ensure that the opening size proportion is the same as the metal proportion, and enabling metal raw materials to fall into a stirring box 1 through the discharge port 4 as shown in figure 1;

after the opening size of the discharge port 4 is adjusted, the motor 8 is electrified, and the stirring plate 12 is stirred in the stirring box 1 through the matching of the driving gear 9, the driven gear 10 and the rotating shaft 11, so that metal raw materials are mixed, and because the stirring plate 12 is provided with the filtering holes 13 as shown in figure 1, the bonded metal powder can be scattered, and different metal raw materials can be mixed together more fully;

after the metal powder mixes, open hasp on agitator tank 1 and open apron 18, rotation axis 11 is still rotatory this moment, it extrudees filter 14 as shown in fig. 1 to fix the fore-set 19 below stirring board 12, make filter 14 vibrations under spring 16's effect, thereby sieve the metal powder of mixing, prevent that the great metal particles of granule from discharging and using and cause the harm to the 3D printer, the vibration effect and the action of gravity that the large granule metal of crossing out passes through filter 14 fall into storing tank 15, the mixture is discharged the back, take out filter 14 and clear away the metal particles in storing tank 15 the inside, this is exactly this theory of operation of antiseized knot 3D printer metal blank compounding device.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an anti-adhesion 3D printer metal blank compounding device, includes agitator tank (1), motor (8), filter (14), bin outlet (17) and fore-set (19), its characterized in that: the stirring box is characterized in that a material storage box (2) is fixedly welded above the stirring box (1), a feeding hole (3) is formed in the top end of the material storage box (2), a discharging hole (4) is formed in the bottom end of the material storage box (2), a baffle (5) is arranged in the discharging hole (4), a scale plate (6) is fixed on the baffle (5), the baffle (5) is connected with a sliding gear (7), the sliding gear (7) is fixed on the top end of the stirring box (1), a motor (8) is fixed on the material storage box (2) through a bolt, a driving gear (9) is fixed at the tail end of an output shaft of the motor (8), the driving gear (9) is connected with a driven gear (10), the driven gear (10) is fixed on a rotating shaft (11), a bearing of the rotating shaft (11) is fixed at the bottom end of the material storage box (2), and the rotating shaft, and rotation axis (11) both sides evenly distributed have stirring board (12), and it has filtration pore (13) to distribute on stirring board (12) simultaneously, filter (14) set up at agitator tank (1) lower extreme, and filter (14) both sides have seted up storing groove (15) to filter (14) and spring (16) interconnect, the other end of spring (16) is fixed on agitator tank (1) simultaneously, bin outlet (17) are seted up in agitator tank (1) bottom, and bin outlet (17) and apron (18) interconnect, and apron (18) are fixed on agitator tank (1), fore-set (19) are fixed on stirring board (12).

2. The anti-sticking 3D printer metal blank compounding device of claim 1, characterized in that: the storage boxes (2) are symmetrically distributed relative to the stirring box (1), and the storage boxes (2) are of a conical structure.

3. The anti-sticking 3D printer metal blank compounding device of claim 1, characterized in that: the baffle (5) is in meshed connection with the sliding gear (7), the area of the baffle (5) is larger than that of the discharge hole (4), and the baffle (5) is of an L-shaped structure.

4. The anti-sticking 3D printer metal blank compounding device of claim 1, characterized in that: the driving gear (9) is in meshed connection with the driven gear (10), and the diameter of the driving gear (9) is larger than that of the driven gear (10).

5. The anti-sticking 3D printer metal blank compounding device of claim 1, characterized in that: the filter plate (14), the discharge opening (17) and the cover plate (18) are distributed from top to bottom, and the area of the filter plate (14) is larger than that of the discharge opening (17).

6. The anti-sticking 3D printer metal blank compounding device of claim 1, characterized in that: the top column (19) and the rotating plane of the stirring plate (12) are vertically distributed, and the height of the top column (19) is smaller than the distance from the bottom end plane of the stirring plate (12) at the lowest end to the upper plane of the bottom end bulge of the stirring box (1).

7. A mixing method based on the anti-sticking 3D printer metal blank mixing device of claim 1 comprises the following steps: firstly, pouring different metal blank powder into different storage boxes (2), adjusting a baffle (5) according to the proportion of metal ingredients, adjusting the opening size proportion of a discharge port (4) through a scale plate (6) on the baffle (5) to enable the opening size proportion to be the same as the metal proportion, and enabling the metal raw materials to fall into a stirring box (1) through the discharge port (4);

after the opening size of the discharge port (4) is adjusted, a motor (8) is electrified, and a driving gear (9), a driven gear (10) and a rotating shaft (11) are matched to enable a stirring plate (12) to stir in a stirring box (1), so that metal raw materials are mixed, and bonded metal powder can be scattered due to the fact that filtering holes (13) are formed in the stirring plate (12), and different metal raw materials can be mixed together more fully;

after metal powder mixes, open hasp on agitator tank (1) and open apron (18), rotation axis (11) are still rotatory this moment, fix fore-set (19) extrusion filter (14) of stirring board (12) below, make filter (14) vibrations under the effect of spring (16), thereby sieve the metal powder of mixing, prevent that the great metal particles of granule from discharging and being used and cause the harm to the 3D printer, the vibration effect and the action of gravity that the large granule metal of crossing the filter (14) of coming out fall into storing groove (15), the mixture discharges the back, it can to take out filter (14) and clear away the metal particles of storing groove (15) the inside.

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