CN220562178U - 3D printing device for precision die - Google Patents

Abstract

The utility model discloses a 3D printing device of a precision die, which comprises a printing component and a discharging component, wherein the printing component comprises a base, a Z-axis moving mechanism arranged at the top of the base and a printing platform arranged at the top of the Z-axis moving mechanism.

Description

3D printing device for precision die

Technical Field

The utility model relates to the technical field of 3D printing, in particular to a 3D printing device for a precision die.

Background

The 3D printing, namely the rapid prototyping technology, is also called additive manufacturing, is a technology for constructing objects by using powdery metal or plastic and other bondable materials in a layer-by-layer printing mode based on digital model files, is often used for manufacturing models in the fields of mould manufacturing, industrial design and the like, when a 3D printer is required to be used for carrying out continuous printing work for a plurality of times, a worker needs to pay attention to the printing process for a plurality of times, timely carries out material taking work on the printed materials, and after long-time work, great consumption is caused for the energy of the worker, and a precision mould 3D printing device can bring convenience for the worker.

Disclosure of Invention

The utility model aims to provide a 3D printing device for a precision die, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the utility model provides a technical scheme that the 3D printing device of a precision die comprises a printing component and a discharging component, wherein the printing component comprises a base, a Z-axis moving mechanism arranged at the top of the base, a printing platform arranged at the top of the Z-axis moving mechanism, and a heating plate arranged inside the printing platform, and the discharging component comprises a support frame arranged at the top of the base, a rotating motor arranged inside the support frame, a connecting shaft penetrating through the top of the rotating motor, a push plate arranged at one side of the connecting shaft, a cutting sheet arranged at one side of the push plate, a material collecting frame arranged on the front surface of the base and a material collecting elastic net arranged inside the material collecting frame.

Preferably, the top of the base is symmetrically provided with Y-axis moving mechanisms, the Y-axis moving mechanisms are positioned on the outer sides of the Z-axis moving mechanisms, and the inner sides of the Y-axis moving mechanisms are provided with X-axis moving mechanisms.

Preferably, the rotating motor is located on the front face of the Y-axis moving mechanism, and the connecting shaft penetrates through the top of the supporting frame to be connected with the rotating motor.

Preferably, the bottom of the cut material sheet is in contact with the top of the printing platform.

By adopting the technical scheme, the beneficial effects obtained by the utility model are as follows:

according to the utility model, the blanking piece is arranged, after 3D printing is finished, the bottom of a printing material is heated by the heating plate arranged in the printing platform, the viscosity is reduced, then the rotating motor arranged in the supporting frame is started, the connecting shaft arranged at the top is driven to rotate outwards with the pushing plate and the blanking piece, the bottom of the material can be separated after the blanking piece contacts the printing material, the separating plate synchronously pushes the material out towards the direction of the material collecting frame, the material collecting elastic net arranged in the material collecting frame can provide buffering for the falling material, and when a worker performs continuous printing work, the automatic separating and discharging can reduce the working intensity of the worker, so that the separating and discharging process is simpler and more convenient, and convenience is brought to the worker.

Drawings

Fig. 1 is a schematic perspective view of a 3D printing apparatus according to the present utility model.

Fig. 2 is a schematic perspective view of a supporting frame according to the present utility model.

Fig. 3 is a schematic cross-sectional view of a support frame according to the present utility model.

In the figure: 100. a printing component; 101. a base; 102. a Z-axis moving mechanism; 103. a printing platform; 104. a heating plate; 105. a Y-axis moving mechanism; 106. an X-axis moving mechanism.

200. A discharge assembly; 201. a support frame; 202. a rotating motor; 203. a connecting shaft; 204. a push plate; 205. cutting a material sheet; 206. a material receiving frame; 207. and (5) receiving the material elastic net.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1, a 3D printing apparatus for a precision mold;

the printing assembly 100 includes a base 101,3D, which is a rapid prototyping technology, and is also called additive manufacturing, and is often used for manufacturing models in the fields of mold manufacturing, industrial design and the like, a Z-axis moving mechanism 102 installed at the top of the base 101, the base 101 can provide support for the top-installed Z-axis moving mechanism 102, a printing platform 103 installed at the top of the Z-axis moving mechanism 102, the Z-axis moving mechanism 102 can provide support and movement capability for the top-installed printing platform 103, when performing printing operation, the Z-axis moving mechanism 102 can provide movement capability along the Z-axis for the printing platform 103, a heating plate 104 is installed inside the printing platform 103, the printing platform 103 can provide installation space and support for the heating plate 104 installed inside, after finishing printing operation, the material bottom viscosity is reduced by heating the printing platform 103 and printing materials through the heating plate 104 installed inside, so as to perform material taking operation, a Y-axis moving mechanism 105 is symmetrically installed at the top of the base 101, the Y-axis moving mechanism 105 is located at the outer side of the Z-axis moving mechanism 102, the base 101 can provide support and movement capability for the top-installed Y-axis moving mechanism 105 along the Z-axis moving mechanism, and movement capability for the Y-axis moving mechanism 106 can provide movement capability for the Y-axis moving mechanism 106 along the Y-axis moving mechanism 106 when performing movement capability for the moving mechanism 106.

Referring to fig. 1, 2 and 3, a 3D printing device for a precision mold;

the discharge assembly 200 comprises a support frame 201 mounted on the top of the base 101, the base 101 can provide support for the support frame 201 mounted on the top, a rotating motor 202 mounted in the support frame 201, the rotating motor 202 is positioned on the front surface of the Y-axis moving mechanism 105, the support frame 201 can provide mounting space and support for the rotating motor 202 mounted inside, a connecting shaft 203 mounted on the top of the rotating motor 202 is penetrated, the connecting shaft 203 penetrates the top of the support frame 201 to be connected with the rotating motor 202, the rotating motor 202 can provide support for the connecting shaft 203 mounted on the top in a penetrating manner, a push plate 204 mounted on one side of the connecting shaft 203, the connecting shaft 203 can provide support and connection and activity for the push plate 204 mounted on one side, a blanking piece 205 mounted on one side of the push plate 204, the bottom of the blanking piece 205 is contacted with the top of the printing platform 103, the push plate 204 can provide support for the blanking piece 205 mounted on one side, the front of the base 101 is provided with a receiving rack 206, the base 101 can provide support for the receiving rack 206 arranged on the front, the interior of the receiving rack 206 is provided with a receiving elastic net 207, the receiving rack 206 can provide installation space and support for the receiving elastic net 207 arranged on the interior, when a worker is carrying out continuous printing work, after the material finishes printing, a rotating motor 202 arranged in a supporting frame 201 is started to drive a connecting shaft 203 arranged on the top to rotate, the connecting shaft 203 rotates to drive a push plate 204 arranged on one side to rotate with a cutting plate 205, when the push plate 204 is close to the cutting plate 205 to print the material, the cutting plate 205 is closely contacted with a printing platform 103, the material can be separated from the adhesion part of the printing platform 103, the separated material is sent out towards the receiving rack 206 by the push plate 204, and when the material falls into the receiving rack 206, install the material bullet net 207 of receiving in the inside receipts work or material rest 206 can provide the buffering for it, prevents to appear dropping the circumstances that leads to deformation, when carrying out long-time continuous printing work, the energy that the staff consumed can be reduced in automatic separation ejection of compact process to can reduce staff's working strength, make separation ejection of compact process more simple and convenient, bring conveniently for the staff.

Working principle: when needs carry out long-time continuous printing work, after the printer finishes once printing, install the hot plate 104 in printing platform 103 and heat, reduce the adhesion between printing material and the printing platform 103, then install the rotating electrical machines 202 start and drive the connecting axle 203 of top installation in support frame 201 and rotate, drive push pedal 204 and the blank piece 205 of one side installation by connecting axle 203 again and rotate, can separate it when blank piece 205 contact material and printing platform 103 adhesion department, send it to receiving work or material rest 206 by push pedal 204 again after the separation, the material that falls into inside can be buffered to receiving material bullet net 207 of installing in receiving work or material rest 206, accomplish autosegregation ejection of compact work.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (4)

1. A precision die 3D printing device, comprising:

the printing assembly (100) comprises a base (101), a Z-axis moving mechanism (102) arranged at the top of the base (101), a printing platform (103) arranged at the top of the Z-axis moving mechanism (102) and a heating plate (104) arranged inside the printing platform (103);

the discharging assembly (200) comprises a supporting frame (201) arranged at the top of the base (101), a rotating motor (202) arranged in the supporting frame (201), a connecting shaft (203) penetrating through the top of the rotating motor (202), a push plate (204) arranged on one side of the connecting shaft (203), a cutting sheet (205) arranged on one side of the push plate (204), a material collecting frame (206) arranged on the front face of the base (101) and a material collecting elastic net (207) arranged in the material collecting frame (206).

2. The precision die 3D printing device according to claim 1, wherein the top of the base (101) is symmetrically provided with a Y-axis moving mechanism (105), the Y-axis moving mechanism (105) is located at the outer side of the Z-axis moving mechanism (102), and the inner side of the Y-axis moving mechanism (105) is provided with an X-axis moving mechanism (106).

3. The 3D printing device for the precision die according to claim 1, wherein the rotating motor (202) is located on the front face of the Y-axis moving mechanism (105), and the connecting shaft (203) penetrates through the top of the supporting frame (201) to be connected with the rotating motor (202).

4. The precision die 3D printing apparatus of claim 1, wherein the bottom of the cut sheet (205) is in contact with the top of the printing platform (103).