CN109968658A - Cross based on temperature-responsive-band double-layer structure 4D Method of printing - Google Patents

Cross based on temperature-responsive-band double-layer structure 4D Method of printing Download PDF

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Publication number
CN109968658A
CN109968658A CN201910011470.0A CN201910011470A CN109968658A CN 109968658 A CN109968658 A CN 109968658A CN 201910011470 A CN201910011470 A CN 201910011470A CN 109968658 A CN109968658 A CN 109968658A
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printing
temperature
layer
double
pattern
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曾思远
高一聪
冯毅雄
郑浩
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Zhejiang University ZJU
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Zhejiang University ZJU
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/10Processes of additive manufacturing
    • B29C64/106Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material
    • B29C64/118Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using filamentary material being melted, e.g. fused deposition modelling [FDM]
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/30Auxiliary operations or equipment
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/30Auxiliary operations or equipment
    • B29C64/379Handling of additively manufactured objects, e.g. using robots
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/30Auxiliary operations or equipment
    • B29C64/386Data acquisition or data processing for additive manufacturing
    • B29C64/393Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y10/00Processes of additive manufacturing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y30/00Apparatus for additive manufacturing; Details thereof or accessories therefor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y50/00Data acquisition or data processing for additive manufacturing
    • B33Y50/02Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y80/00Products made by additive manufacturing

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Materials Engineering (AREA)
  • Manufacturing & Machinery (AREA)
  • Physics & Mathematics (AREA)
  • Mechanical Engineering (AREA)
  • Optics & Photonics (AREA)
  • Robotics (AREA)

Abstract

The invention discloses a kind of cross based on temperature-responsive-band double-layer structure 4D Method of printing.Selected shape memory polymer material repeats stacking using double-layer structure as unit from the bottom up and is printed, double-layer structure is made of two groups of different blank map pattern layer printing arrangement stacked on top of one another, each single layer in every group of blank map pattern layer prints to identical filling pattern, the blank map pattern layer of upper and lower is respectively the different band pattern of printing angle, band pattern is the textured pattern being made of one group of linear array cross arrangement, and linear array is made of a plurality of parallel arrangement straight line;Accurate temperature heating completes crude product deformation 4D deformation.The present invention overcomes the 4D printed materials of current temperature driving to prepare difficulty, to the problem of small-power deformation response degree difference, the fusion sediment 4D Method of printing by design parameter programming without manufacturing special-thread is realized, the complicated processes that 4D printing technique prepares material are breached.

Description

Cross based on temperature-responsive-band double-layer structure 4D Method of printing
Technical field
The present invention relates to a kind of 4D Method of printings in intellectual material 4D printing field, are based on temperature more particularly, to a kind of The cross of response-band double-layer structure 4D Method of printing, realizing can be programmable without manufacturing special-thread by design parameter Fusion sediment 4D Method of printing.
Background technique
As the materials processing technology developed based on Intellisense material, the preparation for traditional deformable material is mentioned for 4D printing It has supplied to break through the new approaches limited to.For bending deformation, due to the heterogeneity meeting of workpiece volume through-thickness shrinkage degree Cause the crooked behavior of multilayer material, 4D printing is commonly designed the multilayered structure for there are different responses to different structure.Conventional 4D Print deformation process is generally by two kinds of ways of realization: 1. take different materials to constitute two layers of workpiece, pass through the excitation of equal extent Means (magnetic, heat, biological response) reach the deformation effect of 4D via two layers of workpiece different strain-responsive.2. taking a kind of material Material constitutes workpiece entirety, via different degrees of exciting means, reaches 4D print deformation effect.
Have the function of that the workpiece of Premium Features or equipment are usually needed in conjunction with complicated 3D shape and inducement structure unit. Most technologies currently used for creating functional structure can only work in the plane.In the past few years, due to various elder generations Into material occur, the application range of shape-memory material extended.Shape-memory polymer can be via low temperature glass The effect of shape memory is realized in conversion between state and super heated rubber state, and polymer at this time has self-healing property, can be passed through The state when load of temperature restores to a certain extent to first time through extrusion forming, the various technologies for proposition of taking this as a foundation Usually require multiple making steps and special material.
The space layout that 3D printing provides a kind of active active element realizes shape switch technology, wherein especially with the more of precision Material printing is representative, can be used to combine different materials, realize Multiple Shape or reversible deformation by polymer.Respectively to Anisotropic additive (such as expansion ratio or rigidity) can be printed by 3D printing technique, to realize the deformation process of 4D printing.It proposes most First planar structure, after obtaining corresponding triggering, their shape will be changed to preset 3D shape, to make table The relevant function in face is combined with complicated 3D shape.There is shortcomings for 4D deformation under system at present, in molding speed It is high to the process equipment requirement of workpiece when spending fast, need to carry out complicated workpiece planning.And when requiring low to process equipment, Shaping speed is again excessively slow.In reality scene, often demand overcomes both defect scenes.Therefore a kind of pair of process equipment is needed The 4D Method of printing of rapid deformation is able to carry out while of less demanding.
Summary of the invention
In view of the drawbacks of the prior art and Improvement requirement, the invention proposes a kind of programmable bilayer based on temperature-responsive The 4D Method of printing of shape memory structure, including the design and preparation of the double-deck shape memory structure.
The method of the present invention is a single step print procedure, it is only necessary to a fusion sediment 3D printer and polymer material, Autofolding and unstable pop-up based on material, and the sequence realized by programming deforms, it can be achieved that with unprecedented extension The 3D shape in space has the characteristics that simple and multi-functional.
To realize above process, according to the invention adopts the following technical scheme:
1) wire rod of the selected shape memory polymer material as printing, according to the product model that need to be printed according to lower section Formula carries out 3D printing: repeating stacking from the bottom up with double-layer structure and is printed, double-layer structure is mainly by two groups of different fillings Pattern layer printing arrangement stacked on top of one another is constituted, and blank map pattern layer includes multiple single layers, each single layer in every group of blank map pattern layer Identical filling pattern is printed to, single layer corresponds to one layer of slice when 3D printing, and the blank map pattern layer of upper and lower is cross Line pattern, band pattern are the textured patterns being made of one group of linear array, and linear array is straight by a plurality of parallel arrangement at equal intervals Line is constituted;
2) after 3D printing, the crude product that printing obtains is removed, carries out accurate temperature heating so that crude product is square according to the rules Formula deformation waits the cooling 4D print procedure of workpiece to be fully completed, obtains 4D printed product until 4D deformation is fully finished.
4D of the present invention print made of product repeat to constitute from the bottom up by double-layer structure, wherein one layer by identical band figure Case multiple stacking is made, and another layer is also made of band pattern multiple-layer stacked, and the thickness proportion of two kinds of band layers can be arrived in 1:4 4:1 adjustment.
Different double-layer structure and printing technology parameter structure are chosen according to the product model design that need to be printed when printing, gone forward side by side Row slice setting is to obtain printed product of different shapes.
It is adjusted when printing according to arrangement different in the product model design construction filling pattern that need to be printed last accurate The different 4D deformed shapes of temperature heating.Different arrangements refers to that the printing angle of linear array in band pattern is different, printing Angle is substantially rectilinear direction and prints the angle between coordinate system trunnion axis.
The first embodiment are as follows: setting double-layer structure wherein linear array in the band pattern of one group of blank map pattern layer Printing angle is within the scope of 0 ± 22.5 degree or 90 ± 22.5 degree, and in the band pattern of another group of blank map pattern layer of double-layer structure The printing angle of linear array is within the scope of 45 ± 22.5 degree or 135 ± 22.5 degree, and the product after realizing temperature heating is around vertical It is 0 ± 22.5 degree smaller compared to 90 ± 22.5 degree of bending deformation degree in the rotary shaft Deformation of helical of coordinate system trunnion axis.
Second of embodiment are as follows: setting double-layer structure wherein linear array in the band pattern of one group of blank map pattern layer Printing angle within the scope of 0 ± 22.5 degree, and in the band pattern of another group of blank map pattern layer of double-layer structure linear array print Brush angle is within the scope of 90 ± 22.5 degree, and the product after realizing temperature heating is around the rotary shaft for being parallel to printing coordinate system trunnion axis Circular arc bending deformation, it is 0 ± 22.5 degree smaller compared to 90 ± 22.5 degree of bending deformation degree.
The third embodiment are as follows: setting double-layer structure wherein linear array in the band pattern of one group of blank map pattern layer Printing angle within the scope of 45 ± 22.5 degree, and in the band pattern of another group of blank map pattern layer of double-layer structure linear array print Brush angle is within the scope of 135 ± 22.5 degree, and the product after realizing temperature heating is around the rotary shaft spiral shell perpendicular to coordinate system trunnion axis Bending deformation is revolved, it is 0 ± 22.5 degree smaller compared to 90 ± 22.5 degree of bending deformation degree.
The 3D printing is printed to fusion sediment 3D printer, needs to cool down after printing.
When printing not according to the different printing technology parameter coordination filling pattern of the product model design construction that need to be printed The different 4D deformation extents of last accurate temperature heating are adjusted with arrangement.Printing technology parameter refers to print wire when 3D printing Excitation temperature b when wide l, printable layer high h and printing nozzle temperature a and accurate temperature heat, excitation temperature b are accurate temperature Spend the heating temperature of heating.
The 4D deformation extent is by the four of printing line width l, the high h of printable layer and printing nozzle temperature a and excitation temperature b A printing technology state modulator.
The printing line width l setting range is 0.25mm-0.8mm, and the high h of printable layer is 50 μm -200 μm, described Nozzle temperature a is 195 DEG C -240 DEG C when printing, and the excitation temperature b is 65 DEG C -95 DEG C.It can finally make transverse and longitudinal strain can The range reached is 0.05-0.36.
The accurate temperature heating is the mode using heating water bath, and solution composition is distilled water, to the temperature of aqueous solution Degree is accurately controlled, and the temperature of heating process is made to stablize the excitation temperature b in setting.
The shape memory polymer material uses stress-strain response performance good polylactic acid shape memory material when being heated Material.
During method is implemented, one of the principal mode that 3D printing is fusion sediment 3D printing is carried out using polymer wire.It beats When the nozzle of print machine carries out extruding wire vent, polymer material completes first deformation process, and in cooling procedure, material carries out shape The first stage of memory, when heating again to molding workpiece, printing silk will restore to a certain extent to when squeezing through wire drawing State, pass through the shape recovery process superposition realize 4D printing deformation process.
The present invention is edited by each structural parameters and technological parameter to model to design the mould for meeting expected deformation Type, and crude product model is made 3D printer and realizes the process that 4D is printed by way of accurately being heated to material.
Through the invention it is contemplated above technical scheme is compared with the prior art, can achieve the following beneficial effects:
1. institute of the invention is in the 4D print structure of the programmable bilayer shape memory structure of temperature-responsive, main application The shape memory characteristic of polymer material, polymer material has processing performance good, low in cost to require low advantage.
2. the present invention prints polymer material using the method that the 4D of fused glass pellet is printed, with aquogel type material 4D Method of printing is compared, and shaping speed is fast, and processing request is low, does not need extremely special shooting condition and manufacturing equipment;
3. the present invention prints polymer material using the method that the 4D of fused glass pellet is printed, beaten with the 4D of magnetoelectricity technique Print ratio, reduces production cost, simplifies the production technology of material, shortens the manufacturing cycle, realizes the one of structure and function Bodyization manufacture.
The present invention overcomes the 4D printed materials of current temperature driving to prepare difficulty, to small-power deformation response degree difference Problem realizes the fusion sediment 4D Method of printing by design parameter programming without manufacturing special-thread, breaches 4D printing Technology prepares the complicated processes of material.
Detailed description of the invention
Fig. 1 is band pattern arrangement schematic diagram of the invention;
Fig. 2 is the strain effects figure of print temperature different when poly-lactic acid material band-band combines;
Fig. 3 is the strain effects figure of excitation temperature different when poly-lactic acid material band-band combines;
Fig. 4 is the high strain effects figure of printable layer different when poly-lactic acid material band-band combines;
Fig. 5 is the strain effects figure of printing line width different when poly-lactic acid material band-band combines;
Fig. 6 is the strain effects figure of thickness ratio different when poly-lactic acid material band-band combines;
Fig. 7 is the Structural assignments schematic diagram of two different filling patterns used by workpiece in embodiment 1;
Fig. 8 is the deformation process front and back comparison diagram of workpiece in embodiment 1;
Fig. 9 is the Structural assignments schematic diagram of two different filling patterns used by workpiece in embodiment 2;
Figure 10 is the deformation process front and back comparison diagram of workpiece in embodiment 2;
Figure 11 is the Structural assignments schematic diagram of two different filling patterns used by workpiece in embodiment 3;
Figure 12 is the deformation process front and back comparison diagram of workpiece in embodiment 3.
Figure 13 is the Structural assignments schematic diagram of two different filling patterns used by workpiece in embodiment 4;
Figure 14 is the deformation process front and back comparison diagram of workpiece in embodiment 4.
Specific embodiment
In order to make the objectives, technical solutions, and advantages of the present invention clearer, with reference to the accompanying drawings and embodiments, right The present invention is further elaborated.It should be appreciated that the specific embodiments described herein are merely illustrative of the present invention, and It is not used in the restriction present invention.As long as in addition, technical characteristic involved in the various embodiments of the present invention described below Not constituting a conflict with each other can be combined with each other.
Specific implementation process of the present invention are as follows:
1) wire rod of the selected shape memory polymer material as printing, according to the product model that need to be printed according to lower section Formula carries out 3D printing: repeating stacking from the bottom up with double-layer structure and is printed, double-layer structure is mainly by two groups of different fillings Pattern layer printing arrangement stacked on top of one another is constituted, and blank map pattern layer includes multiple single layers, each single layer in every group of blank map pattern layer Identical filling pattern is printed to, single layer corresponds to one layer of slice when 3D printing, and the blank map pattern layer of top is band figure Case, the blank map pattern layer of lower section are band pattern.
As shown in Figure 1, band pattern is the textured pattern linear array that is made of one group of linear array by a plurality of parallel Cloth straight line is constituted.The single layer number of plies in the blank map pattern layer of band pattern and the single layer number of plies in the blank map pattern layer of band pattern It can be the same or different.
2) after 3D printing, the crude product that printing obtains is removed, carries out accurate temperature heating so that crude product is square according to the rules Formula deformation, the mode of specifically used heating water bath, solution composition is distilled water, and the temperature of heating process is made to stablize the essence in setting True excitation temperature b.4D printed product is obtained after deformation.
Specifically, the printing angle θ of linear array is adjusted at 0-180 ° in band pattern.
The printing angle of linear array in 1 layer of band pattern is set within the scope of 0 ± 22.5 degree or 90 ± 22.5 degree, another 1 The printing angle of linear array is able to achieve temperature heating within the scope of 45 ± 22.5 degree or 135 ± 22.5 degree in layer band pattern For product afterwards around the rotary shaft Deformation of helical perpendicular to coordinate system trunnion axis, 0 ± 22.5 degree curved compared to 90 ± 22.5 degree Bent deformation extent is smaller.The printing angle of linear array in 1 layer of band pattern is set within the scope of 0 ± 22.5 degree, another 1 layer of band The printing angle of linear array is within the scope of 90 ± 22.5 degree in pattern, and the product after being able to achieve temperature heating is around being parallel to printing The rotary shaft circular arc bending deformation of coordinate system trunnion axis, it is 0 ± 22.5 degree smaller compared to 90 ± 22.5 degree of bending deformation degree.; The printing angle of linear array in 1 layer of band pattern is set within the scope of 45 ± 22.5 degree, linear array in another 1 layer of band pattern Printing angle within the scope of 135 ± 22.5 degree, be able to achieve temperature heating after product around the rotation perpendicular to coordinate system trunnion axis Shaft Deformation of helical is 0 ± 22.5 degree smaller compared to 90 ± 22.5 degree of bending deformation degree.4D deformation extent is by print wire Four printing technology state modulators of wide l, printable layer high h and printing nozzle temperature a and excitation temperature b.It is bigger to print line width l Deformation extent is bigger, and the high h of printable layer gets over that large deformation is smaller, and printing nozzle temperature a is higher, and deformation extent is smaller, excitation temperature B is higher, and deformation extent is bigger.
Printing line width l setting range is 0.25mm-0.8mm, and the high h of printable layer is 50 μm -200 μm, when the printing Nozzle temperature a is 195 DEG C -240 DEG C, and the excitation temperature b is 65 DEG C -95 DEG C.In specific implementation, printing line width l can set model It encloses for 0.25mm-0.8mm.
Can finally make transverse and longitudinal strain accessible range is 0.05-0.36.
It is different according to the filling pattern of each single layer of the double-deck result before product printing, to the filling pattern of each single layer Excitation temperature b when printing line width l, printable layer high h and printing nozzle temperature a in 3D printing and accurate temperature heat into Row setting and pre-programmed, so that finally achieving product strain is rapidly achieved desired effect.
Each printing technology parameter is tested by single factor test when specific implementation, it is corresponding to obtain each printing technology parameter 4D heat distortion result.
It is remained unchanged in other four printing technology parameters and in the case where identical double-layer structure 3D printing, to print temperature It is adjusted the corresponding deformation extent of the different print temperatures of variation acquisition, as shown in Fig. 2, the point in figure on visible solid line is that this swashs It can reach the maximum value of strain (ordinate) under hair temperature (abscissa), the point on dotted line is can under the excitation temperature (abscissa) Reach the minimum value of strain (ordinate), is the achievable range of strain of corresponding print temperature between two lines.
It is remained unchanged in other four printing technology parameters and in the case where identical double-layer structure 3D printing, to excitation temperature It is adjusted the corresponding deformation extent of the different excitation temperatures of variation acquisition, as shown in figure 3, the point in figure on visible solid line is that this swashs It can reach the maximum value of strain (ordinate) under hair temperature (abscissa), the point on dotted line is can under the excitation temperature (abscissa) Reach the minimum value of strain (ordinate), is the achievable range of strain of corresponding excitation temperature between two lines.
It is remained unchanged in other four printing technology parameters and in the case where identical double-layer structure 3D printing, to printable layer height It is adjusted variation and obtains the high corresponding deformation extent of different printable layers, as shown in figure 4, the point in figure on visible solid line is this dozen It can reach the maximum value of strain (ordinate) under print layer high (abscissa), the point on dotted line is can under the printable layer high (abscissa) Reach the minimum value of strain (ordinate), is the high achievable range of strain of corresponding printable layer between two lines.
It is remained unchanged in other four printing technology parameters and in the case where identical double-layer structure 3D printing, to printing line width It is adjusted the corresponding deformation extent of the different printing line widths of variation acquisition, as shown in figure 5, the point in figure on visible solid line is this dozen It can reach the maximum value of strain (ordinate) under print line width (abscissa), the point on dotted line is can under the printing line width (abscissa) Reach the minimum value of strain (ordinate), is the corresponding printing achievable range of strain of line width between two lines.
It is remained unchanged in other four printing technology parameters and in the case where identical double-layer structure 3D printing, to double-layer structure Thickness ratio be adjusted variation obtain different-thickness than corresponding deformation extent, as shown in fig. 6, the point in figure on visible solid line It is the maximum value that can reach strain (ordinate) under the thickness ratio (abscissa), the point on dotted line is under the thickness ratio (abscissa) It can reach the minimum value of strain (ordinate), be corresponding thickness between two lines than achievable range of strain.
Specific embodiments of the present invention are as follows:
Embodiment 1
(1) the double-deck workpiece threedimensional model for carrying out 4D printing using polymer is established first with 3 d modeling software, is produced Product workpiece size is 10*40*1.5mm3, it is 0.22 that workpiece deformation, which is intended to transverse strain, longitudinal strain 0.22.
(2) polylactic acid is selected as 3D printing shape-memory material, and layering is carried out to threedimensional model using Slice Software and is cut Piece processing sets its printable layer height and printing line width according to the deformation for wanting to reach, and selected line width is 0.4mm, selected A height of 50 μm of layer.Band pattern that the upper layer of workpiece uses 150 single layers, that printing angle is 0 °, lower layer use 150 single layers , printing angle be 45 ° of band pattern, as shown in fig. 7, two layers of thickness proportion is 1:1, hierarchy slicing processing result and knowledge Not Chu each section be input in computer control system;
(3) selecting print temperature at this time is 195 DEG C, is exported by Slice Software to fusion sediment 3D printing machining center, 3D printing process is carried out, and waits workpiece cooling;
(4) heating of accurate temperature is carried out to workpiece after cooling, selected excitation temperature is 85 DEG C, until need to carry out 4D deformation is fully finished.It waits workpiece to cool down 4D print procedure again to be fully completed, workpiece is heated during Fig. 8 is the 4D The comparison diagram of front and back is excited, the left figure of Fig. 8 is after the right figure of Fig. 8 is excitation, to realize around perpendicular to coordinate system level before exciting The rotary shaft Deformation of helical of axis, preparation overall process only needs 24min, when substantially reducing production compared to traditional prints Between.
Embodiment 2
(1) the double-deck workpiece threedimensional model for carrying out 4D printing using polymer is established first with 3 d modeling software, is produced Product workpiece size is 10*40*1.5mm3, it is 0.22 that workpiece deformation, which is intended to transverse strain, longitudinal strain 0.05.
(2) polylactic acid is selected as 3D printing shape-memory material, and layering is carried out to threedimensional model using Slice Software and is cut Piece processing sets its printable layer height and printing line width according to the deformation for wanting to reach, and selected line width is 0.4mm, selected A height of 50 μm of layer.The band pattern that the upper layer of workpiece is 0 ° using the printing angle of 150 single layers, lower layer use 150 single layers Printing angle be 90 ° of band pattern, as shown in figure 9, two layers of thickness proportion is 1:1, hierarchy slicing processing result and knowledge Not Chu each section be input in computer control system;
(3) selecting print temperature at this time is 195 DEG C, is exported by Slice Software to fusion sediment 3D printing machining center, 3D printing process is carried out, and waits workpiece cooling;
(4) heating of accurate temperature is carried out to workpiece after cooling, selected excitation temperature is 85 DEG C, until need to carry out 4D deformation is fully finished.It waits workpiece to cool down 4D print procedure again to be fully completed, workpiece is added during Figure 10 is the 4D Comparison diagram before and after thermal excitation before the left figure of Figure 10 is excitation, after Figure 10 right figure is heating, is realized around being parallel to printing coordinate It is the rotary shaft circular arc bending deformation of trunnion axis, both ends close up downwards bending, and preparation overall process only needs 24min, substantially reduces The production time.
Embodiment 3
(1) the double-deck workpiece threedimensional model for carrying out 4D printing using polymer is established first with 3 d modeling software, is produced Product workpiece size is 10*40*1.5mm3, it is 0.22 that workpiece deformation, which is intended to transverse strain, and longitudinal strain is -0.22.
(2) polylactic acid is selected as 3D printing shape-memory material, and layering is carried out to threedimensional model using Slice Software and is cut Piece processing sets its printable layer height and printing line width according to the deformation for wanting to reach, and selected line width is 0.4mm, selected A height of 50 μm of layer.Band pattern that the upper layer of workpiece uses 150 single layers, that printing angle is 90 °, lower layer use 150 lists Layer, printing angle be 45 ° of band pattern, such as Figure 11, two layers of thickness proportion is 1:1, hierarchy slicing processing result and knowledge Not Chu each section be input in computer control system;
(3) selecting print temperature at this time is 195 DEG C, is exported by Slice Software to fusion sediment 3D printing machining center, 3D printing process is carried out, and waits workpiece cooling;
(4) heating of accurate temperature is carried out to workpiece after cooling, selected excitation temperature is 85 DEG C, until need to carry out 4D deformation is fully finished.It waits workpiece to cool down 4D print procedure again to be fully completed, workpiece is added during Figure 12 is the 4D Comparison diagram before and after thermal excitation, Figure 12 left figure are before exciting, and Figure 12 right figure is to realize after exciting around perpendicular to coordinate system level The rotary shaft Deformation of helical of axis, preparation overall process only need 24min, substantially reduce the production time.
Embodiment 4
(1) the double-deck workpiece threedimensional model for carrying out 4D printing using polymer is established first with 3 d modeling software, is produced Product workpiece size is 10*40*1.5mm3, it is -0.22 that workpiece deformation, which is intended to transverse strain, and longitudinal strain is -0.22.
(2) polylactic acid is selected as 3D printing shape-memory material, and layering is carried out to threedimensional model using Slice Software and is cut Piece processing sets its printable layer height and printing line width according to the deformation for wanting to reach, and selected line width is 0.4mm, selected A height of 50 μm of layer.Band pattern that the upper layer of workpiece uses 150 single layers, that printing angle is 45 °, lower layer use 150 lists Layer, printing angle be -45 ° of band pattern, such as Figure 13, two layers of thickness proportion is 1:1, hierarchy slicing processing result and knowledge Not Chu each section be input in computer control system;
(3) selecting print temperature at this time is 195 DEG C, is exported by Slice Software to fusion sediment 3D printing machining center, 3D printing process is carried out, and waits workpiece cooling;
(4) heating of accurate temperature is carried out to workpiece after cooling, selected excitation temperature is 85 DEG C, until need to carry out 4D deformation is fully finished.It waits workpiece to cool down 4D print procedure again to be fully completed, workpiece is added during Figure 14 is the 4D Comparison diagram before and after thermal excitation, Figure 14 left figure are before exciting, and Figure 14 right figure is to realize after exciting around perpendicular to coordinate system level The rotary shaft Deformation of helical of axis, preparation overall process only need 24min, substantially reduce the production time.

Claims (8)

1. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure, it is characterised in that the following steps are included:
1) selected shape memory polymer material as printing wire rod, according to the product model that need to be printed in the following way into Row 3D printing: it repeats stacking from the bottom up with double-layer structure and is printed, double-layer structure is by two groups of different blank map pattern layer Lower stacking printing arrangement is constituted, and blank map pattern layer includes multiple single layers, and each single layer in every group of blank map pattern layer prints to Identical filling pattern, single layer correspond to one layer of slice when 3D printing, and the blank map pattern layer of upper and lower is band pattern, Band pattern is the textured pattern being made of one group of linear array, and linear array is made of a plurality of straight line of parallel arrangement at equal intervals;
2) after 3D printing, the crude product that printing obtains is removed, carries out accurate temperature heating so that crude product becomes according to regulation mode Shape obtains 4D printed product until 4D deformation is fully finished.
2. a kind of 4D Method of printing of the horizontal double-layer structure of cross-based on temperature-responsive according to claim 1, feature exist In: added when printing according to arrangement different in the product model design construction filling pattern that need to be printed to adjust last accurate temperature The different 4D deformed shapes of heat.
3. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 2, feature Be: setting double-layer structure wherein in the band pattern of one group of blank map pattern layer the printing angle of linear array at 0 ± 22.5 degree Or within the scope of 90 ± 22.5 degree, and the printing angle of linear array exists in the band pattern of another group of blank map pattern layer of double-layer structure Within the scope of 45 ± 22.5 degree or 135 ± 22.5 degree, the product after realizing temperature heating is around the rotation perpendicular to coordinate system trunnion axis Axis Deformation of helical;Double-layer structure is arranged, and wherein the printing angle of linear array exists in the band pattern of one group of blank map pattern layer Within the scope of 0 ± 22.5 degree, and in the band pattern of another group of blank map pattern layer of double-layer structure linear array printing angle 90 Within the scope of ± 22.5 degree, the product after realizing temperature heating becomes around the rotary shaft circular arc bending for being parallel to printing coordinate system trunnion axis Shape;Be arranged double-layer structure wherein in the band pattern of one group of blank map pattern layer the printing angle of linear array in 45 ± 22.5 degree of models In enclosing, and in the band pattern of another group of blank map pattern layer of double-layer structure linear array printing angle in 135 ± 22.5 degree of models In enclosing, product after realizing temperature heating around the rotary shaft Deformation of helical perpendicular to coordinate system trunnion axis,.
4. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 1, feature It is: according to the different cloth of the different printing technology parameter coordination filling pattern of the product model design construction that need to be printed when printing It sets to adjust the different 4D deformation extents of last accurate temperature heating.
5. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 4, feature Be: the 4D deformation extent is by four of printing line width l, printable layer high h and printing nozzle temperature a and excitation temperature b Printing technology state modulator.
6. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 5, feature Be: the printing line width l setting range is 0.25mm-0.8mm, and the high h of printable layer is 50 μm -200 μm, the printing When nozzle temperature a be 195 DEG C -240 DEG C, the excitation temperature b be 65 DEG C -95 DEG C.
7. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 1, feature Be: the accurate temperature heating is the mode using heating water bath, is accurately controlled the temperature of aqueous solution, makes to heat The temperature of process stablizes the excitation temperature b in setting.
8. a kind of 4D Method of printing of the cross based on temperature-responsive-band double-layer structure according to claim 1, feature Be: the shape memory polymer material uses polylactic acid shape-memory material.
CN201910011470.0A 2019-01-07 2019-01-07 Cross based on temperature-responsive-band double-layer structure 4D Method of printing Withdrawn CN109968658A (en)

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WO2021248851A1 (en) * 2020-06-10 2021-12-16 苏州聚复高分子材料有限公司 3d printing data generation method, path planning method, system and storage medium
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CN113635551B (en) * 2021-08-16 2022-12-13 吉林大学威海仿生研究院 Self-folding 4D printing method based on shape memory polymer
CN113829382A (en) * 2021-10-18 2021-12-24 湖州绿色智能制造产业技术研究院 Bionic shell soft mechanical gripper based on SMP (symmetric multi-processing) and manufacturing method thereof
CN113829382B (en) * 2021-10-18 2024-06-04 湖州绿色智能制造产业技术研究院 SMP-based bionic shell soft mechanical claw and manufacturing method thereof
CN113968021A (en) * 2021-10-20 2022-01-25 上海交通大学 4D printing thermal driving deformable material

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