JPH0236925A - Method and device for preparing three-dimensional body - Google Patents

Abstract

PURPOSE: To rapidly, economically obtain a three-dimensional plastic by forming a solid section of an article on a surface of a liquid by using a movable spot beam of a programmed UV light, thereafter remotely separating it by a thickness of one layer from the surface, forming next section, and adhering it to the previous layer to constitute the article, thereby rapidly transferring from a designing stage to a master stage and to its manufacture. CONSTITUTION: UV curable liquid 22 or the like is charged in a container 21, an operating surface 23 is determined, and a UV spot 27 is formed on the surface 23. The spot 27 can move over the surface 23. A position of the spot 27 is controlled by a programming unit 28. When the liquid 22 is hardened to form a solid material, an elevation base 29 is lowered by a program. New liquid 22 is converted into a solid material via the spot 27, and connected to a lower material by adhesion. This step is continued until the three-dimensional article 30 is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application] This invention relates to improvements in methods and apparatus for forming three-dimensional objects from a fluid medium, and more particularly, for forming three-dimensional objects quickly, reliably, accurately, and economically. It relates to three-dimensional modeling that applies lithography (L4 thography) to the production of three-dimensional objects.

[Conventional technology]

When manufacturing parts made of plastic, it is common to first design the part and then painstakingly create a prototype of the part. All of these require considerable time, effort and expense. This design is then reviewed, and this laborious process is often repeated many times until the design is optimal.

After the design is optimized, the next step is its manufacture. In most production, plastic parts are injection molded. Because the cost of design time and tooling is so high, injection plastic parts are usually only practical in mass production. Other methods such as direct machining, vacuum forming and direct molding can be used to manufacture plastic parts. However, these methods are typically only cost effective for short runs of production, and the parts produced are of inferior quality to injection molded parts.

Recently, a very good method of creating three-dimensional objects in a fluid medium has been developed. The fluid medium is selectively hardened by a beam of radiation selectively focused at predetermined points of intersection within a three-dimensional volume of the fluid medium. A typical example of an apparatus for forming such three-dimensional objects is U.S. Pat. No. 2,775,78.
No. 5, No. 4゜041 476, No. 4,078,22
No. 9, No. 4,238,840 No. 4,288,86
No. 1 JP-A-56-144478, Hideo Kodama, “Automatic creation of three-dimensional shapes as a method for displaying three-dimensional information” (Transactions of the Institute of Electronics and Communication Engineers, VOL, J64-CNo., 4゜19)
April 1981), former deo Kodama, Autom
aticmethod for f'abrica
ting a three-dimension
Plasijc model with photo-
hardening polymerReview
of'5Ccientiric Instrument
nts, 52(II) Nov, 1981, and Alan J, Herbert, 5solidObj.
ect Generation, Journal
of' Appliedphotograph E
ngineering, vot, 8+No, 4.
August 1982. All of these devices use various large-scale multiple beam schemes to deliver synergistic energy at a selected point deep within the fluid volume to the exclusion of all other points within the fluid volume. It relies on giving. In this regard, various conventional systems use a pair of electromagnetic radiation beams oriented such that they intersect at specific coordinates. In this case, the various beams may have the same or different wavelengths, or the beams may intersect the same point successively rather than simultaneously. However, in all of these cases, the beam intersection alone receives energy to an energy level sufficient to accomplish the curing process necessary to form a three-dimensional object within the volume of the fluid medium.

(Problems to be Solved by the Invention) Unfortunately, however, such a three-dimensional molding apparatus has many problems in terms of resolution and exposure control. The reduction in radiation intensity as the point of intersection moves deeper into the fluid medium, and the reduction in resolution for forming an image of the focused spot, naturally result in a complex control situation. Absorption, diffusion, dispersion and analysis methods all
Making it difficult to process deep within a fluid medium economically and reliably. Therefore, it was difficult to form extremely thin layers, and automatic lamination was also difficult.

But to be able to move quickly and reliably from the design stage to the prototype stage and then to final production. In particular, the ability to go directly from computer-based design to the prototype virtually immediately for such plastic parts, as well as the long-standing desire for equipment to mass-produce them economically and automatically, has brought new challenges to the field of design and manufacturing. Still.

Therefore, those involved in the development and manufacturing of three-dimensional plastic objects, etc., can avoid the complex focusing, alignment and exposure problems of conventional three-dimensional manufacturing equipment, from the design stage to the prototype stage to manufacturing. It has been recognized that it would be desirable to further develop a more rapid, reliable, economical, and automatic means by which the transfer of data may be carried out quickly. This invention satisfactorily meets all these needs.

SUMMARY OF THE INVENTION The present invention provides successive adjacent cross-sectional layers of this object on the surface of a fluid medium capable of changing its physical state in response to appropriate synergistic energy. A new and improved apparatus for creating three-dimensional objects by forming plates is provided. Successive laminates are automatically tightly integrated as they are formed to form the desired three-dimensional object.

By way of example, and not by way of limitation, in the presently preferred embodiment, the invention utilizes computer-generated graphical ideas in combination with lithography. In other words, in order to apply lithography (modeling) technology to the manufacture of three-dimensional objects and directly manufacture three-dimensional objects from computer instructions, computer-assisted design (CAD) and computer-assisted design are necessary. Manufacturing borrowed from (C
AM) are executed simultaneously. The invention can be used for forming templates and prototypes at the design stage of product development, or as a manufacturing device, or for the formation of purely artistic objects.

As used herein, "stereolithography" refers to methods and apparatus for making objects by "printing" thin layers of curable material, such as infrared ray curable material, on top of each other.

A moving spot beam of programmed UV light that illuminates a surface or layer of a UV (ultraviolet) curable liquid is used to form a solid cross section of an object on the surface of the liquid. after that,
The object is moved in a programmed manner away from the surface of the liquid by the thickness of the layer, after which the next cross-section is formed and adhered to the immediately previous layer to form the object. Continue this process until the entire object is formed.

By means of the method of the invention, virtually any form of object can be formed. Complex shapes are made easier to create by using computer functions to generate program instructions and then send program signals to the stereolithography device.

Of course, other types of curable fluid media can be applied, such as particle irradiation (e.g., electron beam), spraying of abrasive materials through a mask, or chemical reactions by ink jets, or other types of non-ultraviolet radiation. It would not be outside the scope of the invention to practice this invention using any suitable synergistic energy.

By way of example, in practicing the invention, a body of fluid medium capable of solidifying in response to a predetermined energy may first be contained in any suitable container to form successive cross-sectional laminates therein. Confining selected working surfaces of the fluid medium such that

Thereafter, synergistic energy of a suitable type, such as a spot of ultraviolet light, is applied in a graphic pattern to a specified working surface of the fluid medium to form a thin, solid, discrete layer on this surface. As they are formed, successive adjacent layers, each layer representing an adjacent cross-section of the three-dimensional object to be made, are automatically superimposed on each other to unite the layers and form the desired three-dimensional object. form. In this point,
When the fluid medium has hardened and the solid material has been formed as a thin laminate on the working surface, a suitable stage on which the first laminate is fixed is moved by any suitable actuating device, typically all microcomputer etc. under the control of, and moved away from the work surface in a programmed manner. In this way, the solid material initially formed on the working surface is moved away from this surface and new liquid flows into the working surface. A portion of this new liquid is converted into a solid material by a programmed UV light spot to define a new laminate, which is adhesively bonded to the material adjacent to it, i.e. to the immediately preceding laminate. . This process continues until the entire three-dimensional object is formed. After this, the formed object is removed from the container and the device is ready to create another object identical to the first object, or an entirely new object generated by the computer.

The stereolithography method and apparatus of the present invention has many advantages over methods currently used to create plastic objects. That is, the method of the present invention does not require the creation of design layouts and drawings, or the creation of processing drawings and tools. The designer can work directly with the computer and stereolithography equipment and, when satisfied with the design displayed on the computer's output screen, can manufacture the part for direct inspection. If the design needs to be modified, this can be easily done through a calculator;
Then, to confirm that the design change was correct,
You can make another part. If your design requires several parts with interacting design parameters, you can quickly change the design of all parts and recreate them.
The method of the present invention is further advantageous because the entire assembly can be made and tested repeatedly if necessary.

After the design is complete, manufacturing of the parts can begin immediately, avoiding weeks or months of turnaround time between design and manufacturing. The final production rate and cost of parts should be similar to current injection molding costs for short run production, with labor costs even lower than for injection molding. Injection molding is economical only when large numbers of identical parts are required. Three-dimensional manufacturing is useful for short production runs, as no tooling is required and production set-up time is very short. Similarly, design changes and custom parts are easily obtained using this method. Because the parts are easy to manufacture, stereolithography allows the use of plastic parts in many places where parts of metal or other materials are currently used. Furthermore, a plastic model of the object can be made quickly and economically before a decision is made to make parts of expensive metal or other materials.

Therefore, the three-dimensional modeling method and apparatus of the present invention are capable of designing and manufacturing three-dimensional plastic parts quickly, reliably, accurately, and economically using CAD or CAM.
It responds to a long-standing need for a system.

The above and other objects and advantages of the present invention will become apparent from the detailed description of the drawings below.

〔Example〕

The invention will now be described in detail with reference to the drawings.

FIGS. 1 and 2 are flowcharts showing the basic method and apparatus of the present invention for creating a three-dimensional object by stereolithography.

The immobilization of polymers by ultraviolet (UV) irradiation, electron beam visible light, non-visible light irradiation, ink jets or other types of synergistic energy such as reactive chemicals applied through a suitable mask A number of liquid state chemical agents are known that can be induced to transform into plastics. UV-curable chemicals are currently used as inks for high-speed printing.
It is currently used as an adhesive in the coating process of paper and other materials, as well as in other specialized fields.

Three-dimensional modeling is a technology that reproduces graphic objects using various methods. Current examples include photocopying, xerography, and microlithography, such as those used in the manufacture of microelectronic circuits. Computer-generated graphics displayed on a plotter or cathode ray tube are also in the lithographic form, and the image is a computer-encoded image of the object.

Computer-aided design (CAD) and computer-aided manufacturing (CAM) are techniques that apply the power of computers to the design and manufacturing process.

A typical example of CAD is in the field of electronic printed wiring design. A typical example of a CAM is a numerically controlled milling machine, where the design parameters are given as data input to the computer and the design parameters are given as data input to the computer. Once machined, a computer and a milling machine process the metal parts. C
Both AD and CAM are important and rapidly growing technologies.

The main objective of this invention is to utilize computer-generated graphical ideas in combination with UV-curable plastics to simultaneously execute CAD and CAM to create three-dimensional objects directly from computer instructions. That's true. This invention is called three-dimensional modeling, and can be used to form templates and prototypes at the design stage of product development, as a manufacturing device, or as artistic forms.

FIG. 1 broadly explains the three-dimensional modeling method of the present invention. Step 10 in FIG. 1 represents the creation of individual laminates representing the cross-sections of the three-dimensional object to be formed. Step 11, which is typically only performed if step 10 has been performed correctly, combines adjacent laminates formed in succession to form the desired three-dimensional object as programmed in the device. , selectively curing. For this reason, the three-dimensional modeling apparatus of the present invention is capable of using incident radiation, electron beam, other particle irradiation, ink jet,
or a fluid medium capable of changing its physical state, respectively, in response to appropriate synergistic energy, such as a chemical agent applied by spraying through a mask adjacent to the surface of the fluid, e.g. UV curing. A three-dimensional object is created by creating a cross-sectional pattern of the object to be formed on a selected surface of a liquid, etc. successive adjacent laminates representing successive adjacent cross sections of the object are automatically formed;
They are integrated to create a graded layered or laminar configuration of objects, and during such forming steps, three-dimensional objects are formed and lifted from a generally planar or sheet surface of the fluid medium.

The method described above is described in more detail in FIG.

In FIG. 2, step 12 requires containing a fluid medium capable of solidifying in response to a predetermined reactive energy. Step 13 applies this energy as a graphic bang to the selected fluid surface to form a thin discrete layer of solid material on that surface. Each layer represents an adjacent cross section of the three-dimensional object being created. Each such layer is
While practicing this invention, it is desirable to make the three-dimensional object as thin as possible in order to maximize the resolution and accurate reproduction of the three-dimensional object being formed, as well as to reduce production time.

For this reason, an ideal theoretical situation would be such that an object is made from only a selected working surface of the fluid medium, such that an infinite number of laminates are obtained, each laminate having a thickness less than zero. The cured depth is only slightly larger (e.g. 1 mm
(below). By forming such a thin layer, the accuracy of the formed object can be improved, and it is also possible to form a molded part without a support on the surface. Of course, when this invention is used in practice, each laminate is a thin laminate, but suitable bonding is required when bonding to adjacent laminates to form a cross-section and define other cross-sections of the object being formed. The thickness should be such that it has the properties.

In step 14 of FIG. 2, successive adjacent layers or laminates are superimposed on each other as they are formed to integrate the various layers and form the desired three-dimensional object. In the normal practice of this invention, when the fluid medium is cured and the solid material is formed to form a laminate, the laminate is moved away from the working surface of the fluid medium and the previously formed laminate The next laminate is formed in the new liquid displacing it, so that each successive laminate is superimposed with every other cross-sectional laminate (by the natural adhesive properties of the hardened fluid medium) and becomes integral. Become. For this reason, the process of manufacturing such cross-sectional laminates is repeated many times until the entire three-dimensional object is formed. The object is then removed and the device is ready to manufacture another object. This object may be the same as the previous object, or it may be made into a completely new object by replacing the program controlling the three-dimensional modeling device.

3 to 8 illustrate various apparatuses suitable for carrying out the three-dimensional modeling method illustrated in the flowcharts of FIGS. 1 and 2.

As previously mentioned, "stereolithography" is a method and apparatus for making solid objects by "printing" thin layers of a curable material, such as a UV curable material, one on top of the other in succession. U that illuminates the surface or layer of a UV curable liquid
A programmed moving spot beam of V-light is used to form a solid cross-section of the object on the surface of the liquid. After this, in a programmed manner, the object is moved away from the surface of the liquid by a layer thickness to form the next cross section and adhere to the previous layer to define the object. Continue this process until the entire object is formed.

With the method of the invention, virtually any type of object can be shaped. By using the power of a computer to generate program instructions and send program signals to a stereolithography device, complex shapes can be created more easily.

A three-dimensional modeling apparatus according to a presently preferred embodiment is shown in a side sectional view in FIG. A container 21 is filled with a UV curable liquid 22 or the like, and a selected work surface 23 is defined. A programmable source such as ultraviolet radiation 26 creates an ultraviolet spot 27 in the plane of surface 23. Movement of a mirror or other optical or mechanical element (not shown) that is part of the light source 26 may cause the spot 27 to move across the surface 23. The position of spot 27 on surface 23 is controlled by a computer or other programming device 28.

A movable lifting platform 29 inside the container 21 can be selectively raised and lowered. The position of the platform 29 is controlled by a computer 28. When this device operates, 30a, 30b,
A three-dimensional object 30 is formed by stepwise stacking of integrated laminates as shown at 30c.

The surface of the UV curable liquid 22 is kept at a constant height within the container 2] and a spot 27 or other suitable UV light of sufficient intensity is applied to cure the liquid and convert it into a solid material. type of reactive energy is transferred across the work surface 23 in a programmed manner. When the liquid 22 hardens to form a solid material, the lifting platform 29, which was initially just below the working surface 23, is lowered from this working surface in a programmed manner by means of a suitable actuator. In this way, the initially formed solid material comes to be below the surface 23 and the new liquid 22 flows into the surface 23. A portion of this new liquid is converted into a solid material by the programmed UV light spot 27, and this new material is adhesively joined to the underlying material. three dimensional objects 30
Continue this process until the whole is formed. after that,
Object 30 is removed from container 21 and the apparatus is ready to make another object. Thereafter, another object can be created, or by replacing the program on computer 28, a new object can be created.

The curable liquid 22, such as a UV curable liquid, must have several important properties.

(A) This is done so that a practical object formation time can be obtained.
It must cure quickly with available UV light sources. (
B) Must be adhesive so that successive layers adhere to each other. (C) Its viscosity must be low enough so that when the platform moves the object, fresh liquid material flows quickly to the surface. (D) It should absorb UV so that the layer formed is reasonably thin.

(E) a UV-curable liquid and a partially cured liquid that is reasonably soluble in a solvent in the liquid state and reasonably insoluble in the same solvent in the solid state, after the object has been formed; must be able to be washed off. (F) Should be as non-toxic and non-irritating as possible.

The cured material must have the desired properties once it is in the solid state. These properties, like those of other plastic materials in general, are application-related. Color, texture, strength, electrical properties, flammability and flexibility are properties to consider. Furthermore, in many cases
Material cost is also important.

The UV curable material used in the presently preferred embodiment of a practical stereolithography apparatus (e.g., FIG. 3) is Potting Compound, a modified acrylate manufactured by Loctite Lid, Ltd. ) 3
It is 63. A method of making this typical UV curable material is described in US Pat. No. 4,100,141.

That is, the UV curable materials described above can be cured by free radical copolymerization using a myriad of known initiators as free radicals. Such initiators include peroxides such as hydrogen peroxide; organic peroxides such as benzoyl methyl ketone peroxide; azo compounds such as 22'-azobis(isobutyronitrile); hydroperoxide,
Hydroperoxides such as t-butyl hydroperoxide, methyl ethyl ketone hydroperoxide;
A light source 26, which can include peresters that hydrolyze to peracid compounds such as t-butyl perbenzoate, t-butyl peracetate; photosensitive compounds such as benzophenone and benzoin ether, forms the desired details of the object. A spot 27 of UV light is generated that is small enough to be able to cure, and strong enough to cure the UV curable liquid used as quickly as practical. The source 26 is configured to be turned on and off and can be programmed to move the focusing spot 27 across the surface 23 of the liquid 22.

For this reason, when the spot 27 moves, it or the liquid 22
is cured into a solid and draws a solid pattern on the surface in much the same way that a chart recording or drafting device uses a pen to draw a pattern on paper.

The light source 26 of the presently preferred embodiment of the stereolithography apparatus uses a 350 watt short-arc mercury lamp located within the housing, and the light output of the housing is coupled to a 1 mm diameter UV-transparent optical fiber bundle (shown in the figure). (not) focused at the edge. The end of the bundle near the mercury lamp was water cooled, and an electronically controlled shutter plate was provided between the lamp and the end of the bundle to turn the light through the bundle on and off.

The bundle was 1 m long and the light output was fed into a lens tube with a quartz lens to focus the UV to a spot. Light source 26 is capable of producing a spot slightly less than 1 mm in diameter and has a longwave UV intensity of about 1 watt/cJ.

In the apparatus of FIG. 3, means are provided to keep the surface 23 at a constant height and to replenish this material after the object has been removed, so that the focal spot 27 remains sharply focused on a constant focal plane. , thus ensuring maximum resolution when forming thin layers along the working surface. In this respect, a focal point is formed to obtain a region of high strength on the working surface 23, which quickly diverges to a lower strength, limiting the depth of the curing process and creating the thinnest area suitable for the object being formed. Preferably, cross-sectional laminates are obtained. This is best accomplished by using a short focal length lens and placing the source 26 as close to the work surface as possible to maximize divergence in the focal cone entering the fluid medium. the result,
Resolution is substantially higher.

H-P manufactured by Heuret Paracard
A Model 9872 digital plotter (not shown) is used to move light source 26. Connect the lens tube to the plotter pen.
The plotter is driven by the computer 28, which is attached to the cartridge and uses conventional graphics commands. The shutter is controlled by a model H-P3497 data acquisition/control unit using computer commands.

Other physical forms of light source 26 or equivalents thereof may be used. Scanning can be performed using an optical scanner, thus eliminating the need for optical fiber bundles and digital blocks. Ultimately, UV lasers become a better light source than similar arc lamps. The speed of the stereolithography process is primarily limited by the intensity of the light source and the response of the UV curable liquid.

Two lifting tables are used to support and hold the object 30 being formed and to move it up and down. Typically, after one layer is formed, the object 30 is moved beyond the level of the next layer (overdip into the liquid medium), leaving the solid at the surface 23 where it was formed. Liquid 2 in temporary space
2 to flow in and then return to the correct height for the next layer. As a result, the liquid 22 that has flowed into the cavity recedes like a receding tide, forming a layer of a predetermined thickness. This allows automatic lamination of extremely thin layers. The requirements for the platform 29 are that it be able to move as programmed with reasonable speed and accuracy, and that it be strong enough to withstand the weight of the object being formed. moreover,
Manual fine adjustment of the position of the lifting platform is helpful during the setup phase as well as when removing objects.

The lifting platform 29 in the embodiment shown in FIG. 3 is an analog plotter (
(not shown).

This plotter, under the program control of the computer 28,
H-P349 with internal digital to analog converter
Powered by a Type 7 data acquisition/control unit.

The computer 28 of the three-dimensional modeling apparatus of this invention basically has two functions. First, it helps the operator design a three-dimensional object in such a way that it can be created. Second, convert this design into appropriate commands for stereolithography and send these commands so that the object is formed. In some applications, the design of the object exists and the computer's only action is to send out appropriate commands or commands.

In the ideal case, the operator can design an object and view it in three dimensions on the CRT screen of computer 28. When the operator completes the design, he commands the computer 28 to create the object, and the computer issues appropriate commands for three-dimensional modeling.

In a practical example of this invention, the computer 28 is H-
P9816 and uses the basic operating system. A typical program is shown in the attached reference material. In this system, the operator
- Program using Graphic Language (command structure for 3497A) and Basic Language commands. The operator must also set the appropriate exposure time and speed for the UV curing time. In order to operate this device, we create an image of an object and write a program to drive the three-dimensional modeling device to create this object.

The drive for the two lifting platforms may be mechanical, pneumatic, hydraulic or electrical, and optical or electronic circuit feedback may be used to precisely control their position. Lifting platform 29
are typically made of glass or aluminum;
Any material to which the cured plastic material will adhere is suitable.

In some cases, the computer 28 may be unnecessary; especially if only simple shapes are to be made, a simpler dedicated programming device may be used. Alternatively, it may simply execute instructions generated by computer controller 28 or another more complex computer. This is the case when some stereolithography devices are used to create an object and another device is used to initially design the object to be formed.

A computer-controlled pump (not shown) can be used to maintain a constant level of liquid 22 at work surface 23. This necessity is due to the following reasons. That is, when the liquid is exposed to light, it contracts due to a change in its capacitance, and the liquid level changes.

Furthermore, when the two lifting platforms move into the liquid, the volume of the liquid changes, and the liquid level changes accordingly. The thickness of the liquid layer is determined by the depth of the previous layer formed below the liquid level, so if the liquid level is not kept constant, the actual thickness of the layer formed will be less than the desired thickness. This is because the thickness of the layer differs from that of the other layer, and a layer with an accurate thickness cannot be formed. Suitable liquid level sensing devices and feedback circuits known in the art are used to drive a fluid pump or to drive a liquid displacement device to move the platform out of the fluid medium as it moves deeper into the fluid medium. A solid rod (not shown) can be driven to level out changes in fluid volume to maintain a constant fluid level on surface 23. Instead of this, the liquid level 22 sensing the light source 26
It can automatically maintain sharp focus on the work surface 23. All of these alternatives can be easily accomplished with common software working in conjunction with computer controller 28.

After the three-dimensional object 30 is formed, the two lifting platforms are raised and the object is removed from the platforms. Typically, after this, the object is cured in a solid medium, such as acetone, which does not dissolve it.
Ultrasonic cleaning in a solvent that dissolves the liquid state of the uncured fluid medium. The object 30 is then placed under an intense ultraviolet flood, typically a 200 watt/inch UV curing lamp, to complete the curing process.

Furthermore, several containers 21 can be used when practicing the invention. Each container contains a different type of curable material and can be automatically selected by the stereolithography device. In this case, the various materials may be plastics of different colors or may have both insulating and conducting materials available for the various layers of the electronic component.

Other embodiments of the invention will now be described with reference to the other drawings, where like reference numerals are used throughout the drawings to refer to parts similar to those described for the preferred embodiment of the invention shown in FIG. There is.

FIG. 4 shows another type of three-dimensional modeling apparatus. In this case, the UV curable liquid 22 etc. floats on top of the heavier UV transparent liquid 32. Liquid 32 is immiscible with and does not wet curable liquid 22. -For example,
Suitable intermediate liquid layer 32 is ethylene, glycol or heavy water. In the apparatus of FIG. 4, the three-dimensional object 30 is lifted out of the liquid 22 instead of penetrating into the fluid medium as shown in the apparatus of FIG.

A UV light source 26 in FIG. 4 focuses a spot 27 on the interface between liquid 22 and an immiscible intermediate liquid layer (mold release liquid) 32. The UV radiation passes through a suitable UV-transparent window 33 made of quartz or the like supported in the bottom of the container 21. The curable liquid 22 is provided as a very thin layer on top of the immiscible layer 32, thus limiting the depth of curing since ideally a very thin laminate should be produced. There is the advantage of directly limiting the layer thickness instead of relying solely on adsorption etc. For this reason, the formation area is more sharply defined, and if the apparatus shown in FIG. 4 is used, certain surfaces can be formed more smoothly than the apparatus shown in FIG.

Furthermore, the UV curable liquid 22 requires less volume;
It is easier to replace one curable material with another.

The device of FIG. 5 is similar to that of FIG. 3, but with a movable U
Instead of a V light source 26 and a programmed source 26 and focused spot 27, a collimated wide UV light source 35 and a suitable aperture mask 36 are used. The aperture mask 36 is placed as close as possible to the work surface 23 and the UV source 35
The collimated light from the mask 36 passes through the mask 36 to expose the working surface 23, thus creating successive adjacent laminates as in the embodiment of FIGS. 3 and 4.

However, the fixed mask 36 representing the cross-sectional shape of the object to be formed
By using , a three-dimensional object with a constant cross-sectional shape can be obtained. When changing this cross-sectional shape, a new mask 36 for that particular cross-sectional shape must be replaced and properly aligned. Of course, by providing a web of masks (not shown) that is successively moved into alignment with the surface 23, the masks can be changed automatically.

FIG. 6 also shows a three-dimensional modeling apparatus similar to that previously described with respect to FIG. However, in place of the light source 26 and focal spot 27, a cathode ray tube (CRT) 38, a fiber optic faceplate 39 and a water or other template layer 40 are provided. To this end, the image provided by the computer 28 to the CRT 38 forms an image on the UV-emitting phosphor surface of the tube, where it passes through the optical fiber layer 39 and the template layer 40 and into the working surface 23 of the fluid medium 22. In all other respects, the 6th
The apparatus shown forms successive cross-sectional laminates that define the desired three-dimensional object to be formed, just as in the embodiments previously described.

7 and 8 show a three-dimensional modeling apparatus in which the lifting platform 29 has additional degrees of freedom, allowing different sides of the object 30 to be exposed for other construction methods.

Similarly, this stereolithography method can be used as an "add-on" method, and the lift platform 29 can be used to pick up and position additional parts for supplementary stereolithography processing. In this respect, the apparatus shown in FIGS. 7 and 8 is the same as that shown in FIG. 3, except that in the apparatus of FIGS. Or, it differs in that it has a second degree of freedom that rotates under automatic control. In this regard, FIG. 7 shows the adjustable platform 29a in its normal position, and FIG. As a result, a complementary structure 41 formed by three-dimensional modeling can be selectively formed.

Practical stereolithography devices have additional components and subsystems beyond those described above for the devices shown schematically in FIGS. 3-8. For example, a practical device has a frame and housing and a control panel.

Additionally, there may be means for shielding the operator from excess UV and visible light, and for allowing the operator to view the object 30 while it is being formed. Practical equipment has safety measures to control ozone and harmful fumes, as well as high pressure safety protection and interlocking devices. Such practical devices also have a means of effectively shielding sensitive electronic circuitry from noise sources.

As already explained, many other devices can be used to carry out the three-dimensional modeling method of the present invention. For example, instead of UV light source 26, an electron source, a visible light source, a laser light source, a short arc light source, a high energy particle source, an X-ray source, or other radiation source may be used, depending on the reactive energy of the particular balance. Any suitable fluid medium that hardens in response, such as a photopolymerized material, can be used. For example, alpha octadecyl acrylic acid, which has been slightly prepolymerized using UV light, can be polymerized using an electron beam. Similarly, poly(2,3-dichloro-1-profil φ acrylate) can be polymerized using an X-ray beam.

〔Effect of the invention〕

The stereolithography method and apparatus of the present invention has many advantages over methods currently used for manufacturing plastic objects. The method of the present invention does not require the creation of design layouts and drawings, nor does it require the creation of processing drawings and tools. The designer can work directly with the computer and stereolithography equipment, and when satisfied with the design displayed on the computer's output screen, can manufacture the part for direct consideration. When a design needs to be changed, it can be easily done through a computer, and then another part can be made to verify that the change was correct. If a design requires several parts with interacting design parameters, the design of all parts can be quickly changed and recreated. The method of the invention is thus further advantageous because the entire assembly can be made and tested repeatedly, if necessary.

Once the design is complete, manufacturing of the parts can begin immediately, thus avoiding weeks or months between design and manufacturing. The final production rate and cost of parts should be similar to the cost of current injection molding for short run production, and labor costs can be even lower than with injection molding.

Injection molding is economical only when large numbers of identical parts are required. Stereolithography is useful for short-term production. This is because no tools are required and the production set-up time is very short. Similarly, design changes and custom parts are easily obtained using this method. Because the parts are easy to make, stereolithography allows the use of plastic parts in many places where parts of metal or other materials are currently used. Furthermore, a plastic model of the object can be made quickly and economically before a decision is made to manufacture parts of expensive metal or other materials.

Although various three-dimensional modeling devices for carrying out this invention have been described above, it is clear that they all share the idea of drawing a nearly two-dimensional surface and pulling up a three-dimensional object from this surface. .

This invention can quickly produce three-dimensional plastic parts, etc.
To meet a long-standing need for CAD and CAM equipment that can be designed and manufactured reliably, accurately, and economically.

While the invention has been illustrated and described in a particular form, it will be obvious that various modifications may be made within the scope of the invention. Therefore, the present invention is not limited only to the scope of the claims of the present application.

[Brief explanation of the drawing]

1 and 2 are flowcharts showing the basic idea used to implement the three-dimensional modeling method of this invention, and FIG. 3 is a sectional view of a currently preferred embodiment of an apparatus for implementing this invention. FIG. 4 is a cross-sectional view of a second embodiment of the invention, and FIG.
FIG. 6 is a sectional view of a third embodiment of the invention, FIG. 6 is a sectional view of a further embodiment of the invention, and FIGS. FIG. 4 is a partial cross-sectional view of a modified three-dimensional modeling apparatus shown in FIG. 3; 21... Container, 22... UV curable liquid, 23...
・Work surface, 26... Light source, 28... Calculator, 29...
- Lifting platform, 30...object. Applicant's agent Mr. Sato

Claims (1)

[Claims] 1. A method for automatically creating a three-dimensional object from a hardenable fluid medium, comprising: creating data representing a cross section of the three-dimensional object to be created; and hardening that occurs in response to the data. exposing the fluid medium to curing radiation to form a first fluid layer in a first cross-sectional layer; exposing a subsequent fluid layer to curing radiation to form a second cross-sectional layer;
the fluid medium has sufficient absorbency for the curing radiation to form a constituent layer with a thickness of 1 mm or less; bonding said second cross-sectional layer to said first cross-sectional layer while exposing a subsequent fluid layer, thereby forming a three-dimensional object from a plurality of sequentially bonded cross-sectional layers. 2. An apparatus for automatically creating a three-dimensional object from a hardenable fluid medium, comprising: a calculation device that generates data representing a cross section of the three-dimensional object to be created; a container that stores the fluid medium; defining a designated work surface, the fluid medium having sufficient absorbency for the curing radiation to form a constituent layer with a thickness of 1 mm or less, and in response to the data applying the curing radiation; an apparatus for forming three-dimensional objects from a plurality of sequentially bonded cross-sectional layers, comprising: a curing radiation source that exposes the fluid medium to form sequential cross-sectional layers on the work surface. 3. A method for automatically creating a three-dimensional object from a hardenable fluid medium, comprising: creating data representing a cross-section of the three-dimensional object to be created; and applying the fluid medium to a hardening irradiation generated in response to the data. forming a first fluid layer in a first cross-sectional layer by exposing the next fluid layer to curing radiation to form a second cross-sectional layer;
said fluid medium has a thickness of 0.8 mm or less and is exposed to sufficient curing irradiation to form a component layer that is partially unsupported but has sufficient adhesion to said first cross-sectional layer. adhering the second cross-sectional layer to the first cross-sectional layer while exposing the next fluid layer to curing radiation to form the second cross-sectional layer with absorbing properties; method of forming a three-dimensional object from a plurality of sequentially bonded cross-sectional layers. 4. A device for automatically creating a three-dimensional object from a hardenable fluid medium, comprising: a calculation device that generates data representing a cross section of the three-dimensional object to be created; a container containing the fluid medium; A constituent layer is formed that defines a designated working surface, the fluid medium has a thickness of 1 mm or less, and is partially unsupported but sufficiently adhesive to the first cross-sectional layer. a curing radiation source having sufficient absorbency for curing radiation to expose the fluid medium to curing radiation in response to the data to form sequential cross-sectional layers on the work surface; Apparatus for forming three-dimensional objects from sequentially glued cross-sectional layers of. 5. Apparatus according to claim 4, wherein the fluid medium is a photopolymer material. 6. The apparatus of claim 4 for forming a three-dimensional object in which each said cross-sectional layer formed is sufficiently strong to maintain a unitary structure. 7. Apparatus according to claim 4, in which the fluid medium forms a three-dimensional object that responds rapidly to the curing radiation. 8. Apparatus according to claim 4, wherein the fluid medium forms a three-dimensional object that absorbs curing radiation in the ultraviolet spectrum. 9. Apparatus according to claim 4 for forming three-dimensional objects which are adhered to the immediately preceding cross-sectional layer while each cross-sectional layer formed is exposed to radiation. 10. An apparatus for automatically creating a three-dimensional object from a curable fluid medium, comprising: at least one aperture mask representing a cross-section of the three-dimensional object to be formed; a container containing the fluid medium; and a container containing the fluid medium. a medium defines a designated working surface and has sufficient absorbency of the curing radiation to form a constituent layer with a thickness of 1 mm or less; a curing radiation source that forms a laminated cross-sectional layer on the work surface by exposure through a separate aperture mask. 11. A device for automatically creating a three-dimensional object from a hardenable fluid medium, comprising: a calculation device that generates data representing a cross section of the three-dimensional object to be created; a container containing the fluid medium; and a container in which the fluid medium is defining a designated working surface, having sufficient absorbency for curing radiation to form a constituent layer of thickness no greater than 1 mm, and located at the opening between said working surface and the bottom of said container; a mold release fluid; and a curing radiation source responsive to the data to expose the fluid medium to curing radiation through the bottom of the container and the mold release fluid to form a laminated cross-sectional layer on the work surface. A device that forms a three-dimensional object from a plurality of sequentially glued cross-sections. 12. An apparatus for automatically creating a three-dimensional object from a curable fluid medium, comprising: at least one aperture mask representing a cross-section of the three-dimensional object to be created; and the fluid medium defining a designated work surface. a mold release agent and the fluid medium having sufficient absorbency for curing radiation to form a constituent layer with a thickness of 1 mm or less, located between the working surface and the bottom of the container; a plurality of sequentially bonded cross-sectional layers comprising a curing radiation source that exposes curing radiation through the at least one aperture mask and through the container and the release material to form a laminated cross-sectional layer on the working surface; A device that forms three-dimensional objects from objects.