CN105751348B - The preparation method of ceramic 3D printer and ceramic component - Google Patents

Abstract

The preparation method of a kind of ceramic 3D printer of present invention offer and ceramic component, the ceramic 3D printer of pottery kind, including：Frame, three-dimensional motion module, ceramic slurry printhead, air pressure adjustment module and top control module；Three-dimensional motion module is installed in the frame, the three-dimensional motion module and the ceramic slurry printhead drive connection, the air flue of the air pressure adjustment module connects with the ceramic slurry printhead, and module is adjusted with the air pressure respectively for the top control module and the three-dimensional motion module communicates to connect；The top control module controls the three-dimensional motion module to drive the ceramic slurry printhead to be moved along predefined paths with the first set rate according to the model data information of ceramic component to be printed, while what is controlled the air pressure adjustment module to adjust the air pressure in the ceramic slurry printhead and then control the ceramic slurry printhead extrudes slurry with the second set rate.The present invention have it is simple in construction, energy consumption is low, the simple beneficial effect of technological process.

Description

The preparation method of ceramic 3D printer and ceramic component

Technical field

The present invention relates to 3D printing field, more particularly to the preparation method of a kind of ceramic 3D printer and ceramic component.

Background technology

3D printing is new work pieces process manufacturing technology, is characterized in the fabrication process using order from scratch Increasing material manufacturing, and traditional method is gradually to subtract excess stock to subtract material manufacture from having nothing.With traditional manufacture method phase Than the 3D printing technique of increasing material manufacturing has higher flexibility and usability.

At present, the side that ceramic 3D printer is extruded using laser sintered ceramic powders or superhigh temperature fused ceramic powder more Method, although the above method quickly produces complete structure, its is bulky, energy resource consumption is more while needs to protect Atmosphere, floor space is both added, adds cost again.And the workpiece of such technology manufacture due to uneven heating it is even, very Easily causing stress concentration makes workpiece ftracture and prints failure.For the sample of no cracking, typically it is also required to re-start to move back Fire processing, manufacturing process trouble.

The content of the invention

The embodiment of the present invention provides a kind of preparation method of improved ceramic 3D printer and ceramic component；It is existing to solve It is bulky during using ceramic 3D printer to make ceramic component, energy resource consumption is more while needs the technology of protective atmosphere to ask Topic.

The embodiment of the present invention provides a kind of ceramic 3D printer, including：Frame, three-dimensional motion module, ceramic slurry printing Head, air pressure adjustment module and top control module；The three-dimensional motion module is installed in the frame, the three-dimensional motion module With the ceramic slurry printhead drive connection, the air flue of the air pressure adjustment module connects with the ceramic slurry printhead, Module is adjusted with the air pressure respectively for the top control module and the three-dimensional motion module communicates to connect；

The top control module controls the three-dimensional motion module to drive according to the model data information of ceramic component to be printed The ceramic slurry printhead is moved along predefined paths with the first set rate, while controls the air pressure adjustment module adjustment Air pressure in the ceramic slurry printhead and then control the ceramic slurry printhead extrude slurry with the second set rate.

In ceramic 3D printer of the present invention, the three-dimensional motion module includes X-axis slide block, Y-axis sliding block, Z axis Sliding block, the first drive mechanism, the second drive mechanism and the 3rd drive mechanism, first drive mechanism, the second drive mechanism And the 3rd drive mechanism respectively with the top control module communicate to connect；

The Y-axis sliding block is fixedly installed in the frame；

The X-axis slide block and first drive mechanism are respectively arranged on the Y-axis sliding block, first driving machine Structure is used to drive the X-axis slide block to slide along Y-axis；

The Z axis sliding block and second drive mechanism are respectively arranged in the X-axis slide block, second driving machine Structure is used to drive the Z axis sliding block to slide along X-axis；

The ceramic slurry printhead and the 3rd drive mechanism are respectively arranged on the Z axis sliding block, and described Three drive mechanisms are used to drive the ceramic slurry printhead to slide along Z axis.

In ceramic 3D printer of the present invention, the ceramic slurry printhead includes slurry cylinder and is installed on institute The syringe needle on one end of slurry cylinder is stated, the other end of the slurry cylinder adjusts the air flue of module by an airway tube and the air pressure Connection.

In ceramic 3D printer of the present invention, the first heating module and first are provided with the syringe needle outer wall Temperature sensor, first heating module and first temperature sensor communicate to connect with the top control module, institute State the temperature that the first temperature sensor is used to detect syringe needle, temperature, first pre- constant speed of the top control module according to the syringe needle Rate and the second set rate control the first heating module to be heated with corresponding power to the syringe needle.

In ceramic 3D printer of the present invention, in addition to it is arranged at correspondence position in the frame and is used to carrying The shaped platform of the ceramic component printed；The second heating module and second temperature sensing are provided with the top of the shaped platform Device, second heating module and second temperature sensor communicate to connect with the top control module respectively, the top control module The temperature value detected according to the second temperature sensor controls the heating power of second heating module.

In ceramic 3D printer of the present invention, the air pressure adjustment module is provided with for manually adjusting air pressure hand Dynamic knob.

Present invention also offers a kind of preparation method of ceramic component, this method comprises the following steps：

S101, top control module obtain the model data information of ceramic component that will be molded, and according to the pattern number it is believed that If the ceramic component is divided into dried layer by breath；

S102, top control module control three-dimensional motion module driving ceramic slurry printhead to exist successively according to model data information Plane where each layer is moved along predefined paths with the first set rate, while controls the air pressure to adjust mould with mobile Group is adjusted the air pressure in the ceramic slurry printhead and then controls being squeezed with the second set rate for the ceramic slurry printhead Go out slurry, so as to complete the printing to each layer to form the ceramic component semi-finished product；

S103, the ceramic component semi-finished product printed are sintered, ceramic powders is formed by curing ceramic component.

It is further comprising the steps of in the step S102 in the preparation method of ceramic component of the present invention：

The temperature of the syringe needle of ceramic slurry printhead is gathered by the first temperature sensor；

Top control module controls the first heated mould according to the temperature of the syringe needle, the first set rate and the second set rate Block is heated with corresponding power to the syringe needle.

In the preparation method of ceramic component of the present invention, the step S103 includes：

The ceramic component printed is dried, dries and is set not according to the species of different ceramic slurries after finishing Same temperature sintering curre and sintering temperature, and the ceramic component is burnt according to the temperature sintering curre and sintering temperature Knot.

In the preparation method of ceramic component of the present invention, the syringe needle is plastic spike, metal needle or glass Syringe needle；The cross section of the syringe needle is shaped as circle, annular concentric, ellipse, square or rhombus.Compared to prior art, Ceramic 3D printer and the ceramic component preparation method of the present invention has the advantages that：

Due to the ceramic 3D printer that uses of the present invention use air pressure by ceramic slurry shear thinning and with set rate from Syringe needle is extruded, so as to successively print the ceramic component, relative to of the prior art laser sintered and superhigh temperature powder melts Technology, ceramic 3D printer provided by the invention, without protective atmosphere, can also avoid print procedure in printing shaping process In point sintering cause stress concentration so that ceramic component printing failure；

And because ceramic 3D printing technique of the prior art needs to carry out laser sintered ceramic powder in print procedure End or superhigh temperature fused ceramic powder, and the ceramic 3D printer in the present invention in print procedure without carrying out laser sintered pottery Porcelain powder or superhigh temperature fused ceramic powder, but be sintered again after ceramic component printing shaping, it in ceramic 3D without beating Integrated sintering module on print machine, have so that device structure is simpler, simplify technological process, be easy to streamlined production and energy consumption is more Low beneficial effect.

Brief description of the drawings

Fig. 1 is the dimensional structure diagram of the ceramic 3D printer in one embodiment of the present invention；

Fig. 2 is the structural representation of the ceramic slurry printhead of the ceramic 3D printer in one embodiment of the present invention.

Embodiment

The explanation of following embodiment is with reference to additional schema, to illustrate the particular implementation that the present invention can be used to implementation Example.The direction term that the present invention is previously mentioned, such as " on ", " under ", "front", "rear", "left", "right", " interior ", " outer ", " side " Deng being only the direction with reference to annexed drawings.Therefore, the direction term used is to illustrate and understand the present invention, and is not used to The limitation present invention.

In figure, the similar unit of structure is represented with identical label.

Fig. 1 is refer to, Fig. 1 is the structural representation of the preferred embodiment of the ceramic 3D printer of the present invention.

The ceramic 3D printer of the preferred embodiment of the present invention includes frame 10, three-dimensional motion module (non-label), ceramic slurry Expect printhead 30, shaped platform 40, air pressure adjustment module 50 and top control module 60.Wherein, three-dimensional motion module is installed on this In frame 10, three-dimensional motion module and the drive connection of ceramic slurry printhead 30, air pressure adjust the air flue and ceramic slurry of module 50 Material printhead 30 connects, and module 50 is adjusted with air pressure respectively for top control module 60 and three-dimensional motion module communicates to connect.

The three-dimensional motion module is used to drive the ceramic slurry printhead 30 to carry out position change in predetermined three dimensions Change.The top control module 60 controls three-dimensional motion module driving ceramic slurry to beat according to the model data information of ceramic component to be printed Print first 30 is moved along predefined paths with the first set rate, while adjusts ceramic slurry as mobile control pressure adjusts module 50 Expect the air pressure in printhead 30 and then control ceramic slurry printhead 30 to extrude slurry with the second set rate.It is quick so as to realize Accurately print ceramic component semi-finished product, then to the ceramic component semi-finished product be sintered solidification can obtain it is high-precision Ceramic component.

Wherein, the frame 10 includes a pedestal 10a and the first support block 11 and second being arranged on pedestal 10a Support block 12, the parallel interval of 11 and second support block of the first support block 12 are set.Pedestal 10a's is located at the first support block 11 and the second region between support block 12 offer a mounting groove, the shaped platform 40 is installed in the mounting groove.

Wherein, the shaped platform 40 is used to carry ceramic component to be printed, its generally rectangular shaped tabular, is provided with it It is multiple to be used for the cooling cooling duct that but liquid stream is crossed.Each cooling duct both ends cooling medium with outside cooling system respectively Delivery outlet connects with recovery port.So as to be cooled down to the ceramic slurry of some special material compositions, accelerate its curing molding.It is excellent Selection of land, leveling nut is additionally provided with the shaped platform 40, so as to be finely adjusted to shaped platform.

In further embodiments, the top of shaped platform 40 is provided with the second heating module and second temperature sensor, Second heating module and second temperature sensor communicate to connect with top control module 60 respectively.Top control module 60 is according to second temperature The temperature value that degree sensor detects controls the heating power of the second heating module, so as to realize the ceramic component to having printed Semi-finished product are heated.

Wherein, air pressure adjustment module 50 can use the higher electric-controlled type Intelligent air pressure adjustment dress of conventional accuracy To put, it receives the control signal of top control module 60, and adjusts the air pressure in ceramic slurry printhead 30 according to the control signal, from And control the slurry extruded velocity of ceramic slurry printhead 30.Preferably, air pressure adjustment module 50 is additionally provided with for manual Adjust air pressure manual knob 51.

Further, an air-dry machine can also be set in the frame 10, in order to the ceramic component to printing shaping half Finished product carries out air dry cure.

The three-dimensional motion module include X-axis slide block 22, Y-axis sliding block (non-label), Z axis sliding block 24, the first drive mechanism 23, Second drive mechanism (not shown) and the 3rd drive mechanism (not shown).First drive mechanism 23, the second drive mechanism and 3rd drive mechanism communicates to connect with top control module 60 respectively.X-axis, Y-axis and Z axis are vertically formed three dimensions right angle seat two-by-two Mark system.First drive mechanism 23, the second drive mechanism and the 3rd drive mechanism adopt available electronically controlled motor, and certainly, it is not It is limited to this.

Wherein, Y-axis sliding block includes the first Y-axis sliding block 21a and the second Y-axis sliding block 21b being parallel to each other.First Y-axis is slided Block 21a is fixedly installed in the second support block 12 of frame 10.Second Y-axis sliding block 21b is fixedly installed on first of frame 10 On bracer 11.

The drive mechanism 23 of X-axis slide block 22 and first is respectively arranged on Y-axis sliding block, and the first drive mechanism 23 is used to drive X-axis slide block is slided along Y-axis.Specifically, first drive mechanism 23 be connected with one end of the X-axis slide block 22 and can be along Y Axle is slidably mounted on the second Y-axis sliding block 21b, the other end of the X-axis slide block 22 can be slidably mounted to along Y-axis this On one Y-axis sliding block 21a.

The drive mechanism of Z axis sliding block 24 and second is respectively arranged in X-axis slide block 22, and the second drive mechanism is used to drive Z Axle sliding block 24 slides along X-axis；The drive mechanism of ceramic slurry printhead 30 and the 3rd is respectively arranged on Z axis sliding block 24, the Three drive mechanisms are used to drive ceramic slurry printhead 30 to slide along Z axis.

Specifically, as shown in Fig. 2 the ceramic slurry printhead 30 includes substrate 33, the slurry cylinder being installed on substrate 33 31st, the syringe needle 32 and secured adjusted mechanism 35 being installed on one end of slurry cylinder 31, secured adjusted mechanism 35 are installed on the base It is used to fix slurry cylinder 31 on plate 33 and the position to the slurry cylinder 31 is finely adjusted so as to be carried out to the position of the syringe needle 32 Fine setting or correction.The air flue that the other end of the slurry cylinder 31 adjusts module 50 by an airway tube 34 with air pressure connects, should Substrate 33 can be slidably mounted on Z axis sliding block 24 along Z axis.The specification of slurry cylinder 31 can be adjusted as needed, such as 3 Milliliter, the different sizes such as 5 milliliters, 10 milliliters, 30 milliliters and 55 milliliters and 200 milliliters

The material of the syringe needle 32 and big I are adjusted as needed, for example, diameter can from 0.001 millimeter to 5 millimeters, Material includes plastic spike, and metal needle and glass needle are first-class.The cross sectional shape of syringe needle 32 also can required design, its can be circle Shape, annular concentric, ellipse, square, rhombus etc..So that to realize the printing of different accuracy and the printing of different ceramic models.

Wherein, it is also provided with the first heating module and the first temperature sensor on the outer wall of the syringe needle 32, first Heating module and the first temperature sensor communicate to connect with top control module 60 respectively.Ceramics are gathered by the first temperature sensor The temperature of the syringe needle 32 of slurry printhead；Top control module 60 is predetermined according to the temperature of syringe needle 32, the first set rate and second The heating module of speed control first is heated with corresponding power to syringe needle 32.

Preferably, the quantity of ceramic slurry printhead 30 can be 2 or more than 2, so as to realize a variety of ceramic slurries Carry out mixing printing.

Present invention also offers a kind of preparation method of ceramic component, and it mainly uses the ceramic 3D in above-described embodiment to beat Print machine, this method comprise the following steps：

S101, top control module obtain the model data information of ceramic component that will be molded, and according to the pattern number it is believed that If the ceramic component is divided into dried layer by breath；

S102, top control module control three-dimensional motion module driving ceramic slurry printhead to exist successively according to model data information Plane where each layer is moved along predefined paths with the first set rate, while controls the air pressure to adjust mould with mobile Group is adjusted the air pressure in the ceramic slurry printhead and then controls being squeezed with the second set rate for the ceramic slurry printhead Go out slurry, so as to complete the printing to each layer to form the ceramic component semi-finished product；

S103, the ceramic component semi-finished product printed are sintered, ceramic powders is formed by curing ceramic component, side by side Go out binding agent.

Wherein,, can be with after top control module obtains the model data information of ceramic component that will be molded in step S101 The quantity of ceramic slurry according to required for going out the mode data information primary Calculation, therefore, can prompt operating personnel to select The slurry cylinder of corresponding specification is so as to getting out the ceramic slurry of scheduled volume.Also, the ceramic slurry has shear thinning characteristic, makes Obtain ceramic slurry and keep solid-state in static state, and there is mobility in the state of having pressure.In addition, made pottery according to model data information If porcelain part is divided into dried layer, such as the high 100mm of the model data presentation of information ceramic component, therefore the ceramic component is drawn It is divided into 200 layers successively to be printed, each layer of thickness is 0.5mm.

In step s 102, first set rate, second set rate and each layer of thickness will be mutually matched, So that thickness of the ceramic slurry in print procedure in the range of this layer is uniform, and not outlet breakpoint.Also, work as and printed one layer When being switched to another layer, top control module control three-dimensional motion module drives the ceramic slurry printhead to be moved correspondingly along Z axis Distance, then carry out the printing of this layer.

In step s 103, the ceramic component semi-finished product printed in step S102 can be burnt using traditional handicraft Knot solidification.

Further, in step s 102, it is further comprising the steps of：

The temperature of the syringe needle of ceramic slurry printhead is gathered by the first temperature sensor；

Top control module according to the temperature of syringe needle, the first set rate and the second set rate control the first heating module with Corresponding power heats to syringe needle.

Step S103 is specifically included：

The ceramic component semi-finished product printed are dried, dried after finishing according to the species of different ceramic slurries Different temperature sintering curres and sintering temperature are set, and according to the temperature sintering curre and sintering temperature to the ceramic component It is sintered.Such as the ceramic slurry is sintered using 1240 degree of temperature, continues 9 hours when being white clay.The ceramic slurry For yellow mud when, be sintered using 1250 degree of temperature, continue 10 hours.When the ceramic slurry is porcelain mud, using 1300 degree Temperature is sintered, and continues 15 hours.

Specifically, the syringe needle is plastic spike, metal needle or glass syringe needle；Being shaped as the cross section of syringe needle be circular, Annular concentric, ellipse, square or rhombus, so as to realize the printing of different accuracy and the printing of different ceramic components

Ceramic component preparation method provided by the invention melts relative to of the prior art laser sintered and superhigh temperature powder Melt technology, relative to of the prior art laser sintered and superhigh temperature powder melts technology, the present invention avoids without protective atmosphere Point sintering in print procedure causes stress concentration so that ceramic component printing failure, and due to pottery of the prior art Porcelain 3D printing technique needs to carry out laser sintered ceramic powders or superhigh temperature fused ceramic powder in print procedure, and of the invention In ceramic 3D printer without carrying out laser sintered ceramic powders or superhigh temperature fused ceramic powder in print procedure, but Go to be sintered again after the completion of printing, therefore, there is the beneficial effect that structure is simpler, technological process is simpler and lower energy consumption Fruit.

In summary, although the present invention is disclosed above with preferred embodiment, above preferred embodiment simultaneously is not used to limit The system present invention, one of ordinary skill in the art, without departing from the spirit and scope of the present invention, it can make various changes and profit Decorations, therefore protection scope of the present invention is defined by the scope that claim defines.

Claims (5)

1. A kind of 1. ceramic 3D printer, it is characterised in that including：Frame, three-dimensional motion module, ceramic slurry printhead, air pressure Adjust module and top control module；The three-dimensional motion module is installed in the frame, the three-dimensional motion module with it is described Ceramic slurry printhead drive connection, the air flue of the air pressure adjustment module connects with the ceramic slurry printhead, described total Control module and adjust module and three-dimensional motion module communication connection with the air pressure respectively；

   The top control module is according to the model data information of ceramic component to be printed controls the three-dimensional motion module driving Ceramic slurry printhead is moved along predefined paths with the first set rate, while is controlled described in the air pressure adjustment module adjustment Air pressure and then the control ceramic slurry printhead in ceramic slurry printhead extrude slurry with the second set rate；

   The ceramic 3D printer also includes being arranged at the ceramic component for being used for carrying and printing of correspondence position in the frame Shaped platform；The second heating module and second temperature sensor, second heating are provided with the top of the shaped platform Module and second temperature sensor communicate to connect with the top control module respectively, and the top control module is according to the second temperature The temperature value that sensor detects controls the heating power of second heating module；Multiple use are provided with the shaped platform In the cooling cooling duct that but liquid stream is crossed, each cooling duct both ends export with the cooling medium of outside cooling system respectively Mouth connects with recovery port.
2. 2. ceramic 3D printer according to claim 1, it is characterised in that the three-dimensional motion module include X-axis slide block, Y-axis sliding block, Z axis sliding block, the first drive mechanism, the second drive mechanism and the 3rd drive mechanism, first drive mechanism, Two drive mechanisms and the 3rd drive mechanism communicate to connect with the top control module respectively；

   The Y-axis sliding block is fixedly installed in the frame；

   The X-axis slide block and first drive mechanism are respectively arranged on the Y-axis sliding block, and first drive mechanism is used Slided in driving the X-axis slide block along Y-axis；

   The Z axis sliding block and second drive mechanism are respectively arranged in the X-axis slide block, and second drive mechanism is used Slided in driving the Z axis sliding block along X-axis；

   The ceramic slurry printhead and the 3rd drive mechanism are respectively arranged on the Z axis sliding block, and the described 3rd drives Motivation structure is used to drive the ceramic slurry printhead to slide along Z axis.
3. 3. ceramic 3D printer according to claim 2, it is characterised in that the ceramic slurry printhead includes slurry cylinder And the syringe needle on one end of the slurry cylinder is installed on, the other end of the slurry cylinder is adjusted by an airway tube and the air pressure The air flue connection of mould preparation group.
4. 4. ceramic 3D printer according to claim 3, it is characterised in that be provided with the first heating on the syringe needle outer wall Module and the first temperature sensor, first heating module and first temperature sensor with the top control module Communication connection, first temperature sensor are used to detecting the temperature of syringe needle, the top control module according to the temperature of the syringe needle, First set rate and the second set rate control the first heating module to be heated with corresponding power to the syringe needle.
5. 5. ceramic 3D printer according to claim 1, it is characterised in that the air pressure adjustment module is provided with for hand Dynamic adjustment air pressure manual knob.