CN209737867U

CN209737867U - Ceramic 3D printer

Info

Publication number: CN209737867U
Application number: CN201821158373.1U
Authority: CN
Inventors: 王晖; 毛好喜; 肖宏涛
Original assignee: Foshan Polytechnic
Current assignee: Foshan Polytechnic
Priority date: 2018-07-21
Filing date: 2018-07-21
Publication date: 2019-12-06
Anticipated expiration: 2028-07-21

Abstract

The utility model discloses a ceramic 3D printer, which is characterized by comprising a frame, a working area arranged on the frame, a 3D printing device, a feeding device, a mechanical arm type milling cutter device, a drying device and a waste recovery device, wherein the 3D printing device comprises a printing arm, a printing spray head and a position adjusting mechanism I; the mechanical arm type milling cutter device is arranged outside the 3D printing device and comprises a position adjusting mechanism II, a milling cutter arm and a milling cutter clamp arranged on the milling cutter arm; the printing arm and the milling cutter arm respectively extend to the working area to switch work; the drying device is arranged outside the working area and is used for drying in the product printing process; the waste recovery device is arranged outside the working area, and dust is absorbed in the working process of the mechanical arm type milling cutter device, so that ceramic waste is recovered. The utility model discloses simple structure uses convenient operation.

Description

Ceramic 3D printer

Technical Field

The utility model relates to a ceramic manufacture equipment technical field specifically is to relate to a pottery 3D printer.

Background

the 3D printing is a novel workpiece processing and manufacturing technology and is characterized in that sequential additive manufacturing from nothing to nothing is adopted in the manufacturing process, and traditional methods are manufacturing by gradually subtracting redundant materials from the absence to the presence. Compared with the traditional manufacturing method, the 3D printing technology of additive manufacturing has higher flexibility and usability. At present, the method that ceramic powder is sintered to laser or ceramic powder is extruded in ultrahigh temperature melting is adopted to ceramic 3D printer more, but can't guarantee out gluey temperature, consequently, the product often need go on further processing on the milling machine after printing, and the operation is complicated, great reduction production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure, use convenient operation's ceramic 3D printer in order to solve the not enough of prior art.

The utility model discloses an adopt following technical solution to realize above-mentioned purpose: a ceramic 3D printer is characterized by comprising a frame, a working area, a 3D printing device, a feeding device, a mechanical arm type milling cutter device, a drying device and a waste recovery device,

the 3D printing device comprises a printing arm, a printing nozzle and a first position adjusting mechanism, wherein the printing arm is arranged on the first position adjusting mechanism, and the printing nozzle is connected with the feeding device;

the mechanical arm type milling cutter device is arranged outside the 3D printing device and comprises a position adjusting mechanism II, a milling cutter arm and a milling cutter clamp arranged on the milling cutter arm;

the printing arm and the milling cutter arm respectively extend to the working area to switch work;

The drying device is arranged outside the working area and is used for drying in the product printing process;

the waste recovery device is arranged outside the working area, and dust is absorbed in the working process of the mechanical arm type milling cutter device, so that ceramic waste is recovered.

As a further explanation of the above scheme, the first position adjusting mechanism includes a first rotating base, a first rotating motor connected to drive the first rotating base to rotate, a first upright post arranged on the first rotating base, and a first lifting driving mechanism arranged on the first upright post, and the first lifting driving mechanism is connected to the printing arm.

Furthermore, the printing arm comprises a lifting arm and a swinging stretching arm, the first lifting driving mechanism is connected with the driving lifting arm, the swinging stretching arm is hinged with the lifting arm, and the first swinging driving motor device connected with the driving stretching arm for swinging is arranged on the lifting arm.

Furthermore, a first guide rail is arranged on the first upright post, the first lifting driving mechanism comprises a first lifting driving cylinder and a first lifting sliding block fixed on a first piston rod of the first lifting driving cylinder, the first lifting sliding block is in sliding connection with the first guide rail, and the printing arm is fixed on the first lifting sliding block.

furthermore, the first rotating base comprises a first rotating wheel fixed at the bottom end of the first upright post through a rotating shaft, the first rotating motor is arranged on the printing arm, and a first driving belt is connected between the first rotating motor and the first rotating wheel

Furthermore, the position adjusting mechanism II comprises a rotating base II, a rotating motor II which is connected with and drives the rotating base II to rotate, an upright post II arranged on the rotating base II, and a lifting driving mechanism II arranged on the upright post II, wherein the lifting driving mechanism II is connected with the milling cutter arm.

Furthermore, the milling cutter arm comprises a mechanical stretching rear arm and a mechanical stretching front arm, the lifting driving mechanism I is connected with and drives the mechanical stretching rear arm, the mechanical stretching rear arm is hinged with the mechanical stretching front arm, and the mechanical stretching rear arm is provided with a second swing driving motor device which is connected with and drives the mechanical stretching front arm to swing.

further, a milling cutter fixture is fixed on the mechanically stretched forearm, and a milling cutter is arranged on the milling cutter fixture.

Furthermore, the feeding device adopts a pneumatic driving feeding mode and comprises a pumping pump and a feeding pipe connected between the pumping pump and the printing spray head.

further, the feeding device adopts a screw feeder, and the screw feeder is provided with a conveying pipe connected with the printing nozzle.

Further, drying device includes electric heating device and the fan that corresponds with electric heating device, and the air supply direction of fan is towards work area.

Furthermore, the waste recovery device comprises an air extraction chamber and an exhaust fan arranged in the air extraction chamber.

The utility model adopts the beneficial effect that above-mentioned technical solution can reach is:

The utility model adopts the ceramic 3D printing equipment mainly comprising a 3D printing device, a feeding device, a mechanical arm type milling cutter device, a drying device and a waste recovery device, wherein the 3D printing device comprises a printing arm, a printing spray head and a position adjusting mechanism I, the printing arm is arranged on the position adjusting mechanism I, and the printing spray head is connected with the feeding device; the mechanical arm type milling cutter device is arranged outside the 3D printing device and comprises a position adjusting mechanism II, a milling cutter arm and a milling cutter clamp arranged on the milling cutter arm; the printing arm and the milling cutter arm respectively extend to the working area to switch work; the drying device is arranged outside the working area and is used for drying in the product printing process; the waste recovery device is arranged outside the working area, dust is absorbed in the process of working of the mechanical arm type milling cutter device, ceramic waste is recovered, the operation is simple and convenient, the processing requirement can be met, and the production efficiency is greatly improved.

Drawings

Fig. 1 is a schematic structural view of the present invention;

Fig. 2 is a schematic structural diagram of the present invention.

Description of reference numerals: 1. the automatic printing device comprises a rack 2, a 3D printing device 2-1, a printing arm 2-2, a printing nozzle 2-3, a position adjusting mechanism I2-31, a rotating base I2-32, a rotating motor I2-33, an upright post I2-34, a lifting driving mechanism I3, a feeding device 4, a mechanical arm type milling cutter device 4-1, a position adjusting mechanism II 4-2, a milling cutter arm 4-3, a milling cutter clamp 5, a drying device 6, a waste recovery device 7, a conveying pipe 8 and a working area.

Detailed Description

The technical solution is described in detail with reference to specific embodiments below.

example 1

As shown in fig. 1-2, the utility model relates to a ceramic 3D printer, which comprises a frame 1 and a working area, a 3D printing device 2, a feeding device 3, a mechanical arm type milling cutter device 4, a drying device 5 and a waste recovery device 6 arranged on the frame, wherein the 3D printing device comprises a printing arm 2-1, a printing spray head 2-2 and a position adjusting mechanism 2-3, the printing arm is arranged on the position adjusting mechanism, and the printing spray head is connected with the feeding device; the mechanical arm type milling cutter device 4 is arranged outside the 3D printing device and comprises a position adjusting mechanism II 4-1, a milling cutter arm 4-2 and a milling cutter clamp 4-3 arranged on the milling cutter arm; the printing arm and the milling cutter arm respectively extend to the working area to switch work; the drying device is arranged outside the working area 8 and is used for drying in the product printing process; the waste recovery device is arranged outside the working area, and dust is absorbed in the working process of the mechanical arm type milling cutter device, so that ceramic waste is recovered. The position adjusting mechanism I2-3 comprises a rotating base I2-31, a rotating motor I2-32 connected with and driving the rotating base I to rotate, an upright post I2-33 arranged on the rotating base I, and a lifting driving mechanism I2-34 arranged on the upright post I, wherein the lifting driving mechanism I is connected with the printing arm. The printing arm comprises a lifting arm and a swinging extension arm, a first lifting driving mechanism is connected with the driving lifting arm, the swinging extension arm is hinged with the lifting arm, and a first swinging driving motor device connected with the driving extension arm for swinging is arranged on the lifting arm. The first upright post is provided with a first guide rail, the first lifting driving mechanism comprises a first lifting driving cylinder and a first lifting sliding block fixed on a first piston rod of the first lifting driving cylinder, the first lifting sliding block is in sliding connection with the first guide rail, and the printing arm is fixed on the first lifting sliding block. The first rotating base comprises a first rotating wheel fixed at the bottom end of the first upright post through a rotating shaft, the first rotating motor is arranged on the printing arm, and a first driving belt is connected between the first rotating motor and the first rotating wheel.

furthermore, the position adjusting mechanism II comprises a rotating base II, a rotating motor II connected with and driving the rotating base II to rotate, an upright post II arranged on the rotating base II, and a lifting driving mechanism II arranged on the upright post II, wherein the lifting driving mechanism II is connected with the milling cutter arm 4-2. The milling cutter arm comprises a mechanical stretching rear arm and a mechanical stretching front arm, a lifting driving mechanism I is connected with the mechanical stretching rear arm and drives the mechanical stretching rear arm to be hinged with the mechanical stretching front arm, and a swing driving motor device II connected with the mechanical stretching front arm to swing is arranged on the mechanical stretching rear arm.

Further, the feeding device adopts a screw feeder which is provided with a conveying pipe 7 connected with the printing nozzle. The drying device comprises an electric heating device and a fan corresponding to the electric heating device, and the air supply direction of the fan faces to a working area. The waste recovery device comprises an air extraction chamber and an exhaust fan arranged in the air extraction chamber.

Example 2

In this embodiment, feedway adopts the mode of air pressure drive pay-off, including the material pumping pump with connect the conveying pipe between material pumping pump and print the shower nozzle.

Compared with the prior art, the utility model adopts the ceramic 3D printing device which mainly comprises a 3D printing device, a feeding device, a mechanical arm type milling cutter device, a drying device and a waste recovery device, wherein the 3D printing device comprises a printing arm, a printing spray head and a position adjusting mechanism I, the printing arm is arranged on the position adjusting mechanism I, and the printing spray head is connected with the feeding device; the mechanical arm type milling cutter device is arranged outside the 3D printing device and comprises a position adjusting mechanism II, a milling cutter arm and a milling cutter clamp arranged on the milling cutter arm; the printing arm and the milling cutter arm respectively extend to the working area to switch work; the drying device is arranged outside the working area and is used for drying in the product printing process; the waste recovery device is arranged outside the working area, dust is absorbed in the process of working of the mechanical arm type milling cutter device, ceramic waste is recovered, the operation is simple and convenient, the processing requirement can be met, and the production efficiency is greatly improved. .

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.

Claims

1. A ceramic 3D printer is characterized by comprising a frame, a working area, a 3D printing device, a feeding device, a mechanical arm type milling cutter device, a drying device and a waste recovery device,

2. The ceramic 3D printer according to claim 1, wherein the first position adjusting mechanism comprises a first rotating base, a first rotating motor connected to drive the first rotating base to rotate, a first upright post arranged on the first rotating base, and a first lifting driving mechanism arranged on the first upright post, and the first lifting driving mechanism is connected with the printing arm.

3. The ceramic 3D printer according to claim 2, wherein the printing arm comprises a lifting arm and a swinging extension arm, the lifting driving mechanism I is connected with and drives the lifting arm, the swinging extension arm is hinged with the lifting arm, and a swinging driving motor device I connected with and driving the extension arm to swing is arranged on the lifting arm.

4. the ceramic 3D printer according to claim 2, wherein the first column is provided with a first guide rail, the first lifting driving mechanism comprises a first lifting driving cylinder and a first lifting slider fixed on the first piston rod of the first lifting driving cylinder, the first lifting slider is in sliding connection with the first guide rail, and the printing arm is fixed on the first lifting slider.

5. The ceramic 3D printer according to claim 2, wherein the first rotating base comprises a first rotating wheel fixed at the bottom end of the upright post through a rotating shaft, the first rotating motor is arranged on the printing arm, and a first transmission belt is connected between the first rotating wheel and the first rotating motor.

6. The ceramic 3D printer according to claim 1, wherein the second position adjustment mechanism comprises a second rotary base, a second rotary motor connected to drive the second rotary base to rotate, a second upright post arranged on the second rotary base, and a second lifting drive mechanism arranged on the second upright post, and the second lifting drive mechanism is connected with the milling cutter arm.

7. the ceramic 3D printer according to claim 6, wherein the milling cutter arm comprises a mechanical extension rear arm and a mechanical extension front arm, the lifting driving mechanism I is connected with and drives the mechanical extension rear arm, the mechanical extension rear arm and the mechanical extension front arm are hinged, and the mechanical extension rear arm is provided with a second swing driving motor device which is connected with and drives the mechanical extension front arm to swing.

8. The ceramic 3D printer of claim 1, wherein the mill holder is fixed to the mechanically extendable forearm, the mill holder having a mill disposed thereon.

9. The ceramic 3D printer according to claim 1, wherein the feeding device is driven by air pressure and comprises an extraction pump and a feeding pipe connected between the extraction pump and the printing nozzle,

Or the feeding device adopts a screw feeder which is provided with a conveying pipe connected with the printing nozzle.

10. The ceramic 3D printer of claim 1, wherein the drying device comprises an electric heating device and a fan corresponding to the electric heating device, and the air supply direction of the fan faces the working area; the waste recovery device comprises an air extraction chamber and an exhaust fan arranged in the air extraction chamber.