KR102281427B1 - Build plate for 3D printer - Google Patents

Abstract

The present invention relates to a build plate of a 3D printer. In a build plate installed to be able to ascend and descend on the upper part of a photocurable liquid resin container in a 3D printer and for fixing an output molded by the curing of the liquid resin in a state immersed in the liquid resin, the build plate has a plurality of division planes on the bottom surface that are mutually divided by a guide slit and provide a fixing surface to which the output is fixed and an inclined surface inside the guide slit for reducing the reaction force applied to the build plate by pushing the liquid resin in the lateral direction when the build plate descends. The build plate of the 3D printer of the present invention made as described above, while descending into the container, splits the liquid resin in the container and pushes the liquid resin in both directions to move the liquid resin so that no foreign material remains in the lower part, thereby not causing defects due to foreign substances. In addition, since the guide slit is formed on the bottom surface, the result can be easily separated from the build plate by using the guide slit after printing is completed.

Description

Build plate for 3D printer

The present invention relates to a build plate mounted in a 3D printer, and more particularly, to a build plate of a 3D printer having a structure in which an accurate operation can be implemented and an output can be easily separated.

A 3D printer is a device for producing a three-dimensional drawing implemented on a computer through a CAD program into a physically present three-dimensional object. The method of 3D printing varies depending on the lamination method and the material used, and among them, a lot of technology using liquid resin as a material has been developed.

3D printing using a liquid resin includes a Fused Deposition Modeling (FDM) method, a Digital Light Processing (DLP) method, and a Stereolithography Apparatus (SLA) method. Among these various methods, the DLP method includes a process of placing a photocurable liquid resin in a container, immersing the build plate in the liquid resin, and irradiating light upward through the transparent bottom plate of the container (under the container). do. The liquid resin forms a unit layer by curing in response to the irradiated light. When the build plate is raised and the unit layers are continuously stacked, a target three-dimensional object can be obtained.

FIG. 1 is a view showing a conventional 3D printer 10, and FIG. 2 is a view for explaining a problem of the build plate 15 shown in FIG.

As shown, the 3D printer 10 is a box-type cabinet 11, a container 13 installed horizontally inside the cabinet and accommodating the liquid resin A, and a build plate located on the upper part of the container 13 ( 15), a driving unit 17 for elevating the build plate 15, and a light source 19 for irradiating light upward from the lower portion of the container 13.

The container 13 is a rectangular frame for accommodating the liquid resin A supplied from the outside, and the bottom surface is made of transparent glass. In addition, the build plate 15 is a plate-shaped member opposing the transparent bottom plate 13a of the container in a completely lowered state, and fixes the printing result. The first printed layer is fixed to the bottom of the build plate 15 .

However, the conventional 3D printer 10 described above has a disadvantage of producing defective products when foreign substances Z (bubbles or dust, etc.) remain in the lower portion of the lowered build plate 15 . Moreover, since the bottom surface of the build plate 15 is completely flat and level, the probability of foreign substances falling sideways is very low.

Because of this problem, an expensive 3D printer may be applied with a tilting device that repeatedly tilts the container 13 to discharge air bubbles. However, as the tilting device is a tilting device, there is a risk that the horizontal position of the container 13 may be slightly changed.

In addition, the build plate 15 is affected by the reaction force received from the resin when descending, so it is difficult to implement a precise height. In addition, it is also cumbersome to separate the result fixed to the build plate 15 from the build plate after printing is completed.

Domestic Patent Publication No. 10-2017-0081906 (Photocurable 3D printer with an improved resin flow output plate) Domestic Patent Publication No. 10-2143951 (3D printer water tank)

The present invention was created to solve the above problems, and it is an object of the present invention to provide a build plate of a 3D printer, which does not cause defects due to foreign substances, and can easily separate the result from the bill plate after printing is completed.

The build plate of the 3D printer of the present invention as a means of solving the problem for achieving the above object is installed so as to be liftable on the upper part of the photocurable liquid resin container in the 3D printer, and the liquid resin is cured in a state immersed in the liquid resin In the build plate for fixing the output to be molded by, the build plate has a plurality of division planes that are mutually divided by a guide slit on a bottom surface and provide a fixing surface to which the output is fixed, the guide slit Inside, it is characterized in that an inclined surface is formed to reduce the reaction force applied to the build plate by pushing the liquid resin in the lateral direction when the build plate is lowered.

In addition, the build plate takes the form of a square plate, and the guide slit has a predetermined width and extends in a straight line parallel to each other.

In addition, the build plate takes the shape of a disk, and the guide slit has a predetermined width and extends in a straight line parallel to each other.

And, the build plate takes the shape of a disk, and the guide slit extends outwardly from the center of the build plate.

In addition, the guide slit is curved in a spiral while extending outward from the center.

In addition, in the central portion of the guide slit in the extension direction, an entry start portion that contacts the liquid resin level and divides the liquid resin left and right is positioned when the build plate is lowered, and the inclined surface is symmetrical about the entry start portion and is opposite to each other direction and slope upwards.

In addition, the entry start part is a bent entry part having an obtuse angle as a part where the inclined surfaces meet.

In addition, the entry start part is located between the inclined surfaces and is a curved entry part having a shape curvedly protruding downward.

In addition, the entry start part is located between the inclined planes and is a planar entry part parallel to the dividing plane.

In addition, in the center of the bottom surface of the build plate, when the build plate is lowered, an entry start part is formed to contact the liquid level of the liquid resin and guide the liquid resin to the guide slit, and the inclined surface extends radially from the entry start part and is upward. inclined

The build plate of the 3D printer of the present invention made as described above, while descending into the container, splits the liquid resin in the container and pushes it in both directions, thereby preventing foreign substances from remaining in the lower part, thereby not causing defects due to foreign substances, and also When descending, it is less affected by the reaction force from the liquid resin.

In addition, since the guide slit is formed on the bottom surface, the result can be easily separated from the bill plate by using the guide slit after printing is completed.

1 is a view showing the structure of a conventional general 3D printer.
FIG. 2 is a view for explaining a problem of the build plate shown in FIG. 1 .
3 is an exploded perspective view of a build plate device to which a build plate according to an embodiment of the present invention is applied.
4 is an inverted perspective view of a build plate according to an embodiment of the present invention.
5 is a partial cross-sectional view for explaining the operation of the build plate shown in FIG.
6 is a perspective view illustrating a modified example of a build plate according to an embodiment of the present invention.
7 is a perspective view illustrating another modified example of the build plate according to an embodiment of the present invention.
8 is a perspective view showing another modified example of the build plate according to an embodiment of the present invention.
9A to 9E are cross-sectional views of a build plate showing a guide slit that can be applied to a build plate according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

The build plate of the present invention uses the kinetic energy when the photocurable liquid resin descends to the lower part of the liquid level, and pushes and moves the liquid resin in the lateral direction, thereby preventing foreign substances from remaining under the build plate. In addition, by reducing the reaction force caused by the liquid resin, it is possible to realize the exact height of the build plate, so that more precise output can be obtained.

The build plate is installed so as to be liftable on the upper part of the photocurable liquid resin container in the 3D printer, and in the build plate for fixing the output formed by curing the liquid resin in a state immersed in the liquid resin, the build plate is, on the bottom surface, mutually divided by a guide slit, has a plurality of division planes providing a fixing surface to which the output is fixed, and inside the guide slit, the liquid resin is pushed in the side direction when the build plate is lowered. It has a structure in which an inclined surface is formed to reduce the reaction force applied to the build plate.

3 is an exploded perspective view of the build plate device 30 to which the build plate is applied according to an embodiment of the present invention, and FIG. 4 is an inverted perspective view of the build plate according to an embodiment of the present invention. 5 is a partial cross-sectional view for explaining the operation of the build plate shown in FIG.

As shown, the build plate device 30 includes a plate-shaped build plate 40 and a lifting holder 31 . The lifting holder 31 is capable of lifting and lowering from the upper portion of the container 13 while being supported by a driving unit (eg, 17 in FIG. 1 ) built into the 3D printer. The elevating holder 31 fixes the build plate 40 to a detachable lower portion thereof. It is possible to use multiple types of lifting holder 31 in one lifting holder 31 in a replaceable manner.

Two support holes 31a are formed in the lifting holder 31 . The support hole 31a is a through hole having a predetermined inner diameter, and receives and supports the insertion support part 41 of the build plate 40 .

The insertion support part 41 is a mounting means integral with the upper surface of the build plate 40, and has a vertical rod 41a and a male screw part 41b. The vertical rod 41a is a cylindrical member having a predetermined diameter and extending vertically. In addition, the male screw part 41b is a vertical headless bolt having a male screw thread.

The insertion support part 41 is inserted into the support hole 31a when the build plate 40 is brought into close contact with the bottom surface of the elevating holder 31, and the male screw part 41b protrudes above the support hole 31a. . When the fixing nut 33 is coupled to the protruding male screw portion 41b, the mounting of the build plate 40 to the elevating holder 31 is completed.

On the other hand, the build plate 40 takes the form of a square plate, and has a plurality of division planes 43 and guide slits 45 on the bottom surface. The division plane 43 is a planar portion divided at regular intervals by the guide slit 45, has a predetermined width and is parallel to each other. This dividing plane 43 is a flat surface and provides a fixing surface to which the output is fixed. The dividing plane 43 is a fixing surface. The principle or process of fixing the output to the dividing plane 43 is a general matter in the 3D printer.

The guide slit 45 is a straight groove having a predetermined width, extending in a straight line parallel to each other, and opening downward. The lower is the direction toward the light-transmitting bottom plate (13a) of the container (13).

In particular, on the inside of the guide slit 45, a bent entry portion 45b and an inclined surface 45a are provided. The bent entry part 45b is an obtuse-angle bent part that protrudes downwardly formed at the point where the inclined surfaces 45a meet. When the build plate 40 descends, it first contacts the liquid level of the liquid resin and then descends to remove the liquid resin. It is the entry start part that starts dividing left and right. The bent entry part 45b is located at the center of the guide slit 45 in the longitudinal direction. The first contact means the first contact with respect to the inclined surface 45a.

The inclined surface 45a is symmetrical with respect to the entry start portion, that is, the bent entry portion 45b, extends in opposite directions with respect to each other, and is inclined upward. The upward inclination means that the inclined surface rises upward as it moves away from the bent entry part 45b. Accordingly, as shown in FIG. 5 , the bent inlet portion 45b forms a V-shaped protrusion having an obtuse angle, that is, protruding downward.

As described above, the reason for forming the bent inlet portion 45b and the inclined surface 45a in the inner region of each guide slit 45 is that when the build plate 40 descends in the direction of the arrow e, the liquid resin (A) This is to push the liquid resin in the lateral direction, that is, in the direction of the arrow f. In addition, the reason for moving the liquid resin (A) by pushing it in the arrow f direction is to reduce the vertical reaction force by the liquid resin and to expel foreign substances that may remain under the build plate from the vertical lower space of the build plate.

By applying the guide slit 45 of the above structure, it is possible to quickly and precisely control the vertical height of the build plate 40 immersed in the liquid resin A, and the probability of occurrence of defects due to foreign substances is significantly reduced. Further, it is also easy to separate the output for the build plate 40 . The output fixed to the dividing plane 43 can be easily removed by inserting an appropriate tool between the output and the inclined surface 45a.

6 is an inverted perspective view showing a modified example of the build plate 40 according to an embodiment of the present invention.

Hereinafter, the same reference numerals as the above reference numerals denote the same elements having the same function, and repeated description thereof will be omitted.

The build plate 40 shown in FIG. 6 takes the form of a disk having a certain diameter and thickness, and a plurality of division planes 43 parallel to each other are formed on the bottom surface, and a guide slit is formed between the division planes 43 . (45) is located.

7 is an inverted perspective view showing another modified example of the build plate 40 according to an embodiment of the present invention.

The build plate 40 shown in FIG. 7 takes the form of a disk having a predetermined diameter and thickness, and has a planar entry portion 45f and a plurality of inclined surfaces 45a on the bottom surface. The planar entry part 45f is formed in the center of the bottom surface of the build plate 40, and when the build plate descends, first comes into contact with the liquid level of the liquid resin (A) and leads the liquid resin to the guide slit (45). am. The first contact means that the liquid resin enters the lower part of the liquid level first compared to the inclined surface 45a.

In order to guide the liquid resin to the guide slit 45, a guide ramp 45g is formed on the outer peripheral surface of the planar entry part 45f. The liquid resin A flows into the guide slit 45 through the guide ramp 45g.

The guide slit 45 has a predetermined width and extends radially from the planar entry portion 45f. The number of guide slits 45 to be applied may vary as much as necessary. In addition, the inclined surface 45a formed in the guide slit 45 is inclined upward in the extending direction. In other words, the height from the light transmitting bottom plate 13a increases toward the outer portion of the build plate 40 .

8 is a perspective view showing another modified example of the build plate 40 according to an embodiment of the present invention.

The build plate 40 shown in FIG. 8 is similar to the build plate shown in FIG. 7, only the shape of the guide slit is different. That is, the guide slit 45 shown in FIG. 8 takes a spirally curved shape. The spiral guide slit 45 receives the liquid resin induced through the induction ramp 45g and sends it out to the outer part of the build plate.

9A to 9E are cross-sectional views of a build plate showing various examples of guide slits that can be applied to the build plate 40 according to an embodiment of the present invention.

In the case of the build plate 40 shown in FIG. 9A , the bent entry part 45b as the entry start part descends to the same height as the dividing plane 43 . The bent-type entry part 45b is a portion where the lower ends of both inclined surfaces 45a meet, and has an obtuse angle. In addition, the extended end of the inclined surface 45a extending in the opposite direction with the bent entry portion 45b therebetween meets the edge of the upper surface 40a of the build plate 40 .

In addition, in the build plate 40 of FIG. 9b , the bent entry part 45b is located above the dividing plane 43 .

The build plate 40 of FIG. 9c has, as an entry start part, a planar entry part 45f in the center of the bottom surface of the build plate 40 . The planar entry part 45f has the same plane as the dividing plane 43 .

The guide slit 45 in the build plate 40 shown in FIG. 9D has a curved surface portion 45c at the outer end of the straight inclined surface 45a. The curved portion 45c is connected to the extended end of the inclined surface 45a and is curved upward, and meets the edge of the upper surface 40a of the build plate 40 .

The build plate 40 of FIG. 9E is positioned between the inclined surfaces 45a and has a curved entry part 45e in a shape curvedly protruding downward. The curved entry part 45e is the entry start number that enters toward the liquid level of the liquid resin, and takes a curved shape toward the bottom.

As mentioned above, although the present invention has been described in detail through specific embodiments, the present invention is not limited to the above embodiments, and various modifications are possible by those of ordinary skill within the scope of the technical spirit of the present invention.

10: 3D Printer 11: Cabinet 13: Container
13a: transparent bottom plate 15: build plate 17: driving part
19: light source 30: build plate device 31: lifting holder
31a: support hole 33: fixing nut 40: build plate
40a: upper surface 41: insertion support 41a: vertical rod
41b: male thread part 43: split plane 45: guide slit
45a: inclined surface 45b: bent entry part 45c: curved part
45e: curved entry part 45f: flat entry part 45g: guide ramp

Claims (10)

In the build plate which is installed so as to be able to move up and down on the upper part of the photocurable liquid resin container in the 3D printer, and for fixing the output formed by curing the liquid resin in a state immersed in the liquid resin,
The build plate, on the bottom surface, is mutually divided by a guide slit, and has a plurality of division planes providing a fixing surface to which the output is fixed,
A build plate of a 3D printer, characterized in that an inclined surface is formed inside the guide slit to reduce the reaction force applied to the build plate by pushing the liquid resin in the lateral direction when the build plate is lowered. According to claim 1,
The build plate takes the form of a square plate,
The guide slit has a predetermined width and a build plate of a 3D printer, characterized in that it extends in a straight line parallel to each other. According to claim 1,
The build plate takes the shape of a disk,
The guide slit has a predetermined width and a build plate of a 3D printer, characterized in that it extends in a straight line parallel to each other. According to claim 1,
The build plate takes the form of a disk,
The guide slit is a build plate of a 3D printer, characterized in that extending outwardly from the center of the build plate. 5. The method of claim 4,
The guide slit is
A build plate of a 3D printer, characterized in that it is curved in a spiral while extending from the center to the outside. 4. The method of claim 2 or 3,
In the central portion of the guide slit in the extension direction, an entry start portion that contacts the liquid resin level and divides the liquid resin left and right is located when the build plate is lowered,
The inclined surface is symmetrical about the entry start part, extends in opposite directions with respect to each other, and is inclined upward. 7. The method of claim 6,
The entry start unit,
The build plate of a 3D printer, characterized in that it is a bent-type entry part having an obtuse angle as a part where the inclined surfaces meet. 7. The method of claim 6,
The entry start unit,
A build plate of a 3D printer, characterized in that it is located between the inclined surfaces and is a curved entry part having a shape curvedly protruding downward. 7. The method of claim 6,
The entry start unit,
A build plate of a 3D printer, which is located between the inclined surfaces and is a planar entry part parallel to the dividing plane. 6. The method according to claim 4 or 5,
At the center of the bottom of the build plate,
When the build plate is lowered, an entry start part is formed that comes into contact with the liquid level of the liquid resin and guides the liquid resin to the guide slit,
The inclined surface extends in a radial direction from the entry start part and is inclined upward.

Images