CN111590889A - Three-dimensional printing equipment - Google Patents

Abstract

The invention provides three-dimensional printing equipment which comprises a printing cavity, a printing platform, a platform motion driving mechanism, a printing spray head, an air electric heating box, a heating device and a convection fan, wherein the printing cavity is provided with a printing cavity air outlet, the printing spray head is positioned above the printing platform, a hot air channel is arranged on the printing spray head, the air electric heating box is arranged outside the printing cavity, a heating element is arranged in the air electric heating box, an electric heating box air inlet and an electric heating box air outlet are arranged on the air electric heating box, the electric heating box air outlet is communicated with the hot air channel, and the electric heating box air inlet is communicated with the printing cavity air outlet. Print platform, platform motion actuating mechanism, printing shower nozzle and the device that generates heat all set up in printing the cavity, and the device and the convection current fan setting of generating heat are in print platform's below, and the device that generates heat includes a plurality of infrared heat radiation lamps that encircle around the convection current fan. The three-dimensional printing equipment can reduce the warping deformation of the three-dimensional printed product.

Description

Three-dimensional printing equipment

Technical Field

The invention relates to the technical field of three-dimensional printing, in particular to three-dimensional printing equipment capable of reducing warping of a three-dimensional printed product.

Background

Today, when the industry and the manufacturing industry develop at a high speed, the traditional manufacturing industry processing technology cannot meet a plurality of processing requirements of high precision, high complexity and special shape, and under the promotion of various processing requirements of high requirements and high standards, a new rapid forming method is produced: and (4) three-dimensional printing. The three-dimensional printing technology is one of the most popular and vital technologies in the novel manufacturing field at present by virtue of a plurality of advantages, the technology is different from a common printer which can only move in a two-dimensional direction, the three-dimensional printing utilizes a three-dimensional CAD data model, a control machine carries out layer-by-layer accumulation operation on printing materials, the solid reduction of a 3D model is realized through accumulation, and the manufacturing mode not only shortens the development period but also reduces the research and development cost when complex parts are produced.

However, in the stacking process of the molten plastic, the internal stress generated by volume shrinkage always causes the warpage deformation of a prototype, and if the internal stress causes the delamination seriously, even the molding cannot be carried out, the warpage deformation is the main reason for influencing the precision and the quality of a printed product, and under the condition of a certain layer thickness, the factors influencing the warpage are mainly the temperature and the filling rate, so that the research on how to reduce the warpage is very important for the further popularization and application of the three-dimensional printing technology.

Disclosure of Invention

The invention aims to provide three-dimensional printing equipment capable of reducing warping deformation of a three-dimensional printing product so as to solve the warping problem in the printing of high-temperature thermoplastic plastics at present.

In order to achieve the purpose, the invention provides three-dimensional printing equipment which comprises a printing chamber, a printing platform, a platform movement driving mechanism, a printing spray head, an air electric heating box, a heating device and a convection fan, wherein the printing chamber is provided with a printing chamber air outlet, the outer wall of the printing chamber is wrapped with a cavity heat insulation layer, the printing platform is used for bearing a three-dimensional printing product, the platform movement driving mechanism drives the printing platform to move in a three-dimensional space, the printing spray head is positioned above the printing platform, the printing spray head is provided with a hot air channel, the air electric heating box is arranged outside the printing chamber, a heating element is arranged in the air electric heating box, the air electric heating box is provided with an electric heating box air inlet and an electric heating box air outlet, the electric heating box air outlet is communicated with the hot air channel, and the electric heating box. Print platform, platform motion actuating mechanism, printing shower nozzle and the device that generates heat all set up in printing the cavity, and the device that generates heat includes a plurality of infrared heat radiation lamps, and the device and the convection current fan that generate heat all set up in print platform's below, and the central point at printing the cavity diapire is installed to the convection current fan puts, and a plurality of infrared heat radiation lamps encircle around the convection current fan.

It is seen by above-mentioned scheme that heat gas through air electric heating box to the realization is to the heat preservation of printing the shower nozzle, makes three-dimensional printing goods be heated evenly, and can realize gas cyclic utilization, resources are saved, the pollution abatement. The infrared heat radiation lamp heats the hot circulating air, the infrared heat radiation lamps surround the convection fan, and the convection fan can uniformly mix heat emitted by the infrared heat radiation lamps and gas inside the printing cavity, so that the temperature distribution in the printing cavity is uniform. In addition, the cavity effectively reduces the heat dissipation to the outside by wrapping the heat-insulating material, so that the temperature of the cavity reaches more than 250 ℃, and the temperature uniformity is good. The three-dimensional printing equipment provided by the invention effectively solves the problems that the existing printer is easy to warp when used for printing a three-dimensional product, the temperature of the cavity is not high enough, and the temperature uniformity is not ideal.

Preferably, the three-dimensional printing device further comprises a plasticizing device, a melt gear pump and a droplet jetting device which are connected in sequence. The plasticizing device comprises a hopper, a machine barrel and a plasticizing screw rod, the plasticizing screw rod is installed in the machine barrel and extends in the horizontal direction, the hopper is installed at the top of the machine barrel and is communicated with the machine barrel, and the melt gear pump is installed at the discharge end of the machine barrel. The droplet ejection device includes a molten material inlet and a print head, the molten material inlet being connected to a melt gear pump.

Therefore, the granular plastic raw materials are added into the hopper, the plasticizing screw is used, the melt gear pump is matched for pressure build, and the pneumatic valve needle moves at high speed to realize droplet injection.

The droplet injection device further comprises a valve body, a valve seat, a heating sleeve and a valve needle, wherein the valve seat and the valve body are integrally formed, the heating sleeve is sleeved outside the valve body, the valve needle is installed in the valve body and extends along the vertical direction, the valve needle can impact the valve seat along the vertical direction, a molten material inlet is formed in the peripheral wall of the valve body, and the molten material inlet is communicated with the interior of the valve body.

Therefore, granular plastic raw materials are added into a hopper, the materials are melted, plasticized and transported through a plasticizing screw, pressure is built up through a melt gear pump, the melted materials are conveyed to a droplet injection device in the form of high-temperature and high-pressure melt, the droplet injection device adopts a mechanical firing pin type injection technology, a valve needle is driven by compressed air, local high pressure is generated at the moment when the valve needle impacts a valve seat, the local high pressure drives the melt to overcome external force of surface tension, gravity and the like which hinder the injection of the melt, the melt is ejected from a printing nozzle to form liquid drops, and the technology can reduce warping, and meanwhile, the final formed product has excellent precision and surface finish.

The droplet injection device further comprises an air compressor, a compressed air inlet is formed in the top of the valve body, and high-pressure gas generated by the air compressor enters the valve body through the compressed air inlet and pushes the valve needle to move.

Therefore, the electromagnet can generate a demagnetization phenomenon in a high-temperature environment for a long time, so that the reciprocating motion of the valve needle is invalid, and the effect of droplet injection is influenced, therefore, the injection part of the droplet injection device is pneumatically driven, high-pressure gas generated by the air compressor pushes the valve needle to reciprocate through the compressed air inlet, and the stability of the valve needle motion is ensured.

In a preferred embodiment, the plasticizing screw is nitrided.

Preferably, the plasticizing device further comprises a ceramic heater for heating the plasticizing screw.

Therefore, the ceramic heater has simple structure and uniform heating.

One preferred scheme is that the hot-air channel includes vertical extension and the horizontal extension that links to each other, and the air inlet of hot-air channel sets up the one end of keeping away from vertical extension on the horizontal extension, and vertical extension is cyclic annular, and the air outlet of hot-air channel is located the axis of vertical extension.

Therefore, the materials close to the nozzles in the printing nozzle can be fully and uniformly heated.

Preferably, the air outlet of the electric heating box is connected to the air inlet of the hot air channel via a lightweight, flexible ventilation tube.

In a preferred scheme, a baffle plate is further arranged in the air electric heating box, and the baffle plate is connected to the inner wall of the air electric heating box.

Therefore, the baffle plate can guide the gas flow direction, and prolong the detention time of the gas in the inner cavity of the air electric heating box, so that the gas is fully heated, and the gas is uniformly heated.

The cavity heat insulation layer is of a double-layer structure and comprises an outer polystyrene foam layer and an inner aluminum silicate ceramic fiber layer, and the thickness of the cavity heat insulation layer is not less than 6 cm.

Therefore, good heat insulation effect can be realized.

Drawings

FIG. 1 is a schematic diagram of an embodiment of a three-dimensional printing apparatus of the present invention.

FIG. 2 is a schematic diagram of a printing chamber and an internal structure of an embodiment of a three-dimensional printing apparatus according to the present invention.

Fig. 3 is a schematic view of a droplet ejection device in an embodiment of a three-dimensional printing apparatus of the invention.

Fig. 4 is a top view of an air heating cabinet in an embodiment of the three-dimensional printing apparatus of the present invention.

Fig. 5 is a cross-sectional view at a-a in fig. 4.

The invention is further explained with reference to the drawings and the embodiments.

Detailed Description

Referring to fig. 1 and 2, the three-dimensional printer apparatus of the present embodiment includes a mechanical structure portion and a control system portion, wherein the mechanical structure portion includes a printing chamber 1, a printing stage 2, a stage movement driving mechanism 3, a plasticizing device 4, a melt gear pump 5, a droplet ejection device 6, an air electric heating box 7, a heat generating device 8, and a convection fan 9. The control system part comprises a motion control system, a temperature control system and a pressure control system.

Print chamber 1 and seted up and print chamber gas outlet 11, it has wrapped up cavity insulating layer 12 on the outer wall of chamber 1 to print, and cavity insulating layer 12 is bilayer structure, including outer polystyrene foam layer and the aluminium silicate ceramic fiber layer of inlayer, and the thickness of cavity insulating layer 12 is not less than 6 centimetres.

The printing table 2, the table motion drive mechanism 3, the droplet ejection device 6 and the heat generating device 8 are all disposed within the printing chamber 1. The printing platform 2 is used for bearing a three-dimensional printing product, the droplet jetting device 6 is positioned above the printing platform 2, and the platform motion driving mechanism 3 drives the printing platform 2 to move in a three-dimensional space. Platform motion actuating mechanism 3 includes that the X direction removes the module, the Y direction removes the module and the module is removed to vertical direction, and the Y direction removes module drive print platform 2 and removes along the Y direction, and the X direction removes module drive print platform 2 and removes along the X direction, and vertical direction removes module drive print platform 2 and removes along the Z direction. The platform motion driving mechanism 3 is a common structure in the field of three-dimensional printing, and is a prior art and is not described herein again.

As shown in fig. 2, the plasticizing device 4 includes a hopper 41, a cylinder 42, and a plasticizing screw 43, the plasticizing screw 43 being mounted in the cylinder 42 and extending in a horizontal direction, the hopper 41 being mounted on the top of the cylinder 42 and communicating with the cylinder 42, and a melt gear pump 5 being mounted at a discharge end of the cylinder 42. The plasticizing screw 43 is subjected to nitriding treatment, and the plasticizing screw 43 is heated by a ceramic heater which is simple in structure and uniform in heating.

Referring to fig. 3, droplet ejection device 6 includes a print head 61, a valve body 62, a valve seat 63, a heating jacket 64, and a valve needle 65. The heating jacket 64 is made of copper, the valve needle 65 is made of stainless steel, the valve seat 63 and the valve body 62 are integrally formed and made of carbon steel, and the surface of the valve seat 63 is hardened. The heating sleeve 64 is sleeved outside the valve body 62, the valve needle 65 is installed in the valve body 62 and extends along the vertical direction, the valve needle 65 can impact the valve seat 63 along the vertical direction, a molten material inlet 622 is formed in the peripheral wall of the valve body 62, the molten material inlet 622 is communicated with the interior of the valve body 62, and the molten material inlet 622 of the droplet injection device 6 is connected with the melt gear pump 5. Since the electromagnet will generate demagnetization phenomenon in high temperature environment for a long time, which causes the reciprocating motion failure of the valve needle 65 and affects the droplet ejection effect, the ejection part of the droplet ejection device 6 is pneumatically driven, and the high-pressure gas generated by the air compressor pushes the valve needle 65 to reciprocate through the compressed air inlet 621. The printing nozzle 61 is heated by a high-temperature-resistant ceramic heating body, the printing nozzle 61 is provided with a hot air channel 611, the hot air channel 611 comprises a vertical extension section 6111 and a horizontal extension section 6112 which are connected, an inner thread is arranged on the inner wall of the horizontal extension section 6112, an air inlet of the hot air channel 611 is arranged at one end, far away from the vertical extension section 6111, of the horizontal extension section 6112, the vertical extension section 6111 is annular, and an air outlet of the hot air channel 611 is located on the axis of the vertical extension section 6111.

As shown in fig. 1, 4 and 5, the air heating box 7 is disposed outside the printing chamber 1, the air heating box 7 heats the air flow, and the total length of the heating cavity in the air heating box 7 is in the range of 600 mm to 1200 mm. The air electric heating box 7 is internally provided with a heating element 71 and a plurality of single-arc baffle plates 72, the heating element 71 comprises a stainless steel tube 711 and an electric heating wire, the electric heating wire is arranged in the stainless steel tube 711, magnesium oxide powder is filled in a gap between the electric heating wire and the stainless steel tube 711, metal sheets 712 are uniformly distributed on the outer wall of the stainless steel tube 711, and the metal sheets 712 and the outer wall of the stainless steel tube 711 form an included angle. The baffle plate 72 is attached to the inner wall of the air-electric heating box 7. The baffle plates 72 can guide the gas flow direction, prolong the detention time of the gas in the inner cavity of the air electric heating box 7, so that the gas is fully heated, the gas is uniformly heated, and the metal sheets 712 distributed on the stainless steel pipes 711 can increase the heat exchange area and improve the heat exchange efficiency.

An electric heating box air inlet 73 and an electric heating box air outlet 74 are formed in the box body of the air electric heating box 7, the electric heating box air outlet 74 is connected with an air inlet of the hot air channel 611 through a light telescopic ventilation pipe 75, on one hand, the hot air reduces heat loss of the high-temperature printing spray head 61, on the other hand, the three-dimensional printing product is heated through the constant temperature and the constant speed of the hot air, and warping can be effectively reduced. The electric heating box air inlet 73 is communicated with the printing chamber air outlet 11, so that on one hand, the time for reheating to the required temperature is reduced, the efficiency is improved, the resources are saved, on the other hand, the gas recycling can be realized, and the atmosphere when the printing is carried out by utilizing N2 or other inert gases is protected.

The electric heating box air inlet 73 is provided with a first filter component, which includes a filter screen and absorbent cotton arranged on the filter screen. The air outlet 74 of the electric heating box is provided with a second filtering part, and alumina powder is arranged in the second filtering part. The first filter member and the second filter member are provided to filter the circulating hot air while absorbing moisture in the hot air.

At least one temperature sensor is arranged on the feeding port of the hopper 41, the plasticizing screw 43, the air inlet of the hot air channel 611, the air outlet 74 of the electric heating box, the printing platform 2 and the heating jacket 64 of the droplet ejection device 6, so that the measurement result is more accurate by sampling the temperature data of a plurality of points, the temperature and the uniformity of the temperature distribution in the printing chamber 1 can be conveniently analyzed and determined, and the temperature data is used as a basis for adjusting the rotating speed of the convection fan 9 and the heater power.

As shown in fig. 1 and 2, the heat generating device 8 and the convection fan 9 are both located below the printing platform 2 and are both mounted on the bottom wall of the printing chamber 1. The convection fan 9 comprises a fan blade 91 and a driving part which are connected with each other, the fan blade 91 is arranged in the printing chamber 1 and is positioned below the printing platform 2, and the driving part is positioned outside the printing chamber 1. The convection fan 9 is installed at a central position of the bottom wall of the printing chamber 1, and the heat generating device 8 includes a plurality of infrared heat radiation lamps 81, and the plurality of infrared heat radiation 1 lamps 8 are uniformly surrounded around the convection fan 9. The arrangement of the infrared heat radiation lamp 81 and the convection fan 9 can make the temperature distribution of the entire printing chamber 1 uniform.

After the temperature rise is started, after the temperature including the temperature of hot air is stable, a material to be printed is added into the hopper 41, the material to be printed is melted by the plasticizing screw 43, plasticized and transported, the pressure is built up through the melt gear pump 5, the melted material is conveyed to the droplet injection device 6 in the form of high-temperature and high-pressure melt, the droplet injection device 6 adopts a mechanical firing pin type injection technology, the key of the injection technology is that the valve needle 65 is driven by compressed air, local high pressure is generated at the moment of impacting the valve seat 63, the melt is driven by the local high pressure to overcome the external force of surface tension, gravity and the like which hinder the injection of the melt, so that the melt is ejected from the printing nozzle 61 to form liquid drops, the technology can reduce warping, and the final formed product has excellent precision and.

During the formation of the melt droplet stack, the pressure of the melt in the droplet ejection device 6 must be kept constant. A high-temperature melt pressure sensor is arranged on a flow channel of the melt gear pump 5, pressure closed-loop control is adopted, the collected melt pressure is compared with the upper limit and the lower limit of a set pressure value, and when the melt pressure is higher than the maximum pressure value, the plasticizing screw 43 stops rotating, so that the internal pressure of the micro-flow channel is ejected from the printing nozzle 61 through the melt to release the pressure; when the melt pressure is lower than the minimum pressure value, the plasticizing screw 43 is started to raise the internal pressure of the micro-channel, so that the melt pressure in the micro-channel is kept in a stable range, and meanwhile, the heating sleeve 64 is used for heating and insulating, so that the melt droplets can be uniformly sprayed.

Therefore, the invention converts the traditional melting accumulation mode into droplet ejection stacking, is assisted by a global temperature control system, utilizes hot air for heat preservation and heating, solves the problems that the temperature of a cavity is not uniform due to insufficient hot air circulation at present, and finally the three-dimensional printed product is often warped, and enables the cavity to be heated to a high temperature of more than 250 ℃ by installing a fan motor at the outer side of the heat preservation layer of the cavity and wrapping sufficient heat preservation materials outside the cavity and an air duct, so that the invention can adapt to the molding requirements of almost all common general engineering plastics and special engineering plastics and has good industrial application prospect. The three-dimensional printing equipment is added with the pressure closed-loop control system and the temperature closed-loop control system, so that the stability of the working state of the equipment can be effectively improved, and the compactness of the internal structure and the surface precision of a three-dimensional printing product are improved.

Finally, it should be emphasized that the above-described preferred embodiments of the present invention are merely examples of implementations, not limitations, and various changes and modifications may be made by those skilled in the art, without departing from the spirit and scope of the invention, and any changes, equivalents, improvements, etc. made within the spirit and scope of the present invention are intended to be embraced therein.

Claims (10)

1. Three-dimensional printing apparatus, characterized by comprising:

the printing chamber is provided with a printing chamber air outlet, and the outer wall of the printing chamber is wrapped with a cavity heat insulation layer;

a printing platform for carrying a three-dimensional printed article;

the platform motion driving mechanism drives the printing platform to move in a three-dimensional space;

the printing spray head is positioned above the printing platform, and a hot air channel is formed in the printing spray head;

the air electric heating box is arranged outside the printing cavity, a heating element is arranged in the air electric heating box, an electric heating box air inlet and an electric heating box air outlet are formed in the air electric heating box, the electric heating box air outlet is communicated with the hot air channel, and the electric heating box air inlet is communicated with the printing cavity air outlet;

the printing platform, the platform motion driving mechanism, the printing nozzle and the heating device are all arranged in the printing chamber, and the heating device comprises a plurality of infrared heat radiation lamps;

the printing device comprises a printing platform, a heating device, a convection fan, a plurality of infrared heat radiation lamps and a plurality of infrared heat radiation lamps, wherein the heating device and the convection fan are arranged below the printing platform, the convection fan is arranged at the central position of the bottom wall of the printing cavity, and the infrared heat radiation lamps are surrounded around the convection fan.

2. The three-dimensional printing apparatus according to claim 1, wherein:

the three-dimensional printing equipment further comprises a plasticizing device, a melt gear pump and a droplet jetting device which are connected in sequence;

the plasticizing device comprises a hopper, a cylinder and a plasticizing screw, the plasticizing screw is arranged in the cylinder and extends in the horizontal direction, the hopper is arranged at the top of the cylinder and is communicated with the cylinder, and the melt gear pump is arranged at the discharge end of the cylinder;

the droplet ejection device comprises a molten material inlet and the print head, wherein the molten material inlet is connected with the melt gear pump.

3. The three-dimensional printing apparatus according to claim 2, wherein:

droplet injection apparatus still includes valve body, disk seat, heating jacket and needle, the disk seat with valve body integrated into one piece, the heating jacket cover is established outside the valve body, the needle is installed extend along vertical direction in the valve body, the needle can strike along vertical direction the disk seat, the molten material entry sets up on the perisporium of valve body, the molten material entry with the inside intercommunication of valve body.

4. The three-dimensional printing apparatus according to claim 3, wherein:

the droplet jetting device further comprises an air compressor, a compressed air inlet is formed in the top of the valve body, and high-pressure gas generated by the air compressor enters the valve body through the compressed air inlet and pushes the valve needle to move.

5. The three-dimensional printing apparatus according to any one of claims 2 to 4, wherein:

and the plasticizing screw is subjected to nitriding treatment.

6. The three-dimensional printing apparatus according to any one of claims 2 to 4, wherein:

the plasticizing device further comprises a ceramic heater, and the ceramic heater is used for heating the plasticizing screw.

7. The three-dimensional printing apparatus according to any one of claims 1 to 4, wherein:

the hot-air channel comprises a vertical extension section and a horizontal extension section which are connected, an air inlet of the hot-air channel is arranged at one end, far away from the vertical extension section, of the horizontal extension section, the vertical extension section is annular, and an air outlet of the hot-air channel is located on the axis of the vertical extension section.

8. The three-dimensional printing apparatus according to any one of claims 1 to 4, wherein:

and the air outlet of the electric heating box is connected with the air inlet of the hot air channel through a light telescopic ventilation pipe.

9. The three-dimensional printing apparatus according to any one of claims 1 to 4, wherein:

and a baffle plate is also arranged in the air electric heating box and connected to the inner wall of the air electric heating box.

10. The three-dimensional printing apparatus according to any one of claims 1 to 4, wherein:

the cavity heat insulating layer is of a double-layer structure and comprises an outer polystyrene foam layer and an inner aluminum silicate ceramic fiber layer, and the thickness of the cavity heat insulating layer is not less than 6 cm.

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