阅读说明：本技术 用于使用惰性气体防止在3d打印系统中光引发聚合反应的氧阻聚的系统和方法 (System and method for preventing oxygen inhibition of photoinitiated polymerization reactions in 3D printing systems using inert gases ) 是由 迈克尔·泽诺 吉夫·吉兰 丹尼尔·利普茨 尤瓦尔·谢伊 于 2019-12-04 设计创作，主要内容包括：通过使用惰性气体流从反应表面清除氧气来防止光引发聚合反应的氧阻聚的系统和方法。在一些实施方案中,使用气体扩散系统清除氧气,所述气体扩散系统通过扩散器将惰性气体引入UV光源与工件的可UV固化层之间的工作空间中。所述扩散器可由透明或扩散材料制成以允许UV光穿过它,并包括一系列微孔,用于所述气体穿过朝向所述工件。可加热所述惰性气体流以维持期望且均匀的反应温度。(Systems and methods for preventing oxygen inhibition of photoinitiated polymerization reactions by scavenging oxygen from the reaction surface using a flow of inert gas. In some embodiments, oxygen is purged using a gas diffusion system that introduces an inert gas through a diffuser into the working space between the UV light source and the UV curable layer of the workpiece. The diffuser may be made of a transparent or diffusing material to allow UV light to pass through it and includes a series of micro-holes for the gas to pass through towards the workpiece. The inert gas flow may be heated to maintain a desired and uniform reaction temperature.)

1. A system for preventing oxygen inhibition of photoinitiated polymerization reactions at ambient conditions, said system comprising: an Ultraviolet (UV) light source; a UV curing space for receiving a workpiece having a layer of UV curable material; and means for scavenging oxygen from the UV curing space to facilitate UV curing of the UV curable material within the UV curing space when the UV light source emits light onto the layer of UV curable material.

2. The system of claim 1, wherein the means for scavenging oxygen comprises: a gas diffusion system for introducing an inert gas into a working space between the UV light source and the UV material layer of the workpiece; and a transparent cover separating the UV light source from the workspace, wherein the gas diffusion system and the transparent cover are arranged relative to each other so as to allow inert gas flowing in from one or more gas inlets of the gas diffusion system to flow out through a diffuser towards the workspace.

3. The system of claim 2, wherein the diffuser has a plurality of micro-holes having bridges of UV transparent material disposed over the micro-holes so as to be positioned between respective inlets of the micro-holes and the UV light source.

4. The system of claim 3, further comprising a gas pressure homogenizer to ensure a constant pressure throughout the system.

5. The system of claim 3, wherein the diffuser is made of the UV transparent material to allow UV light from the UV light source to pass through it.

6. The system of claim 3, wherein the micro-holes are sized and spaced relative to each other so as to optimize gas distribution and UV light distribution throughout the workspace.

7. The system of claim 6, wherein the micro-pores are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the workspace and are equal in size such that UV light is approximately uniformly distributed within the workspace.

8. The system of claim 3, wherein the micro-pores are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the workspace and UV light is approximately uniformly distributed within the workspace.

9. The system of claim 3, wherein the temperature of the inert gas is controlled to create a uniform reaction temperature.

10. The system of claim 3, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

11. A method for preventing oxygen inhibition of photoinitiated polymerization reactions at ambient conditions, said method comprising: periodically emitting Ultraviolet (UV) light from a UV light source into a UV curing space in which a workpiece having a layer of UV curable material is disposed to promote UV curing of the UV curable material within the UV curing space and to purge oxygen from the UV curing space when the UV light source emits light onto the layer of UV curable material.

12. The method of claim 11, wherein purging oxygen from the UV curing space comprises: introducing an inert gas into a working space between a UV light source and the UV material layer of the workpiece through a gas diffusion system.

13. The method of claim 12, wherein the inert gas is introduced through one or more gas inlets of the gas diffusion system and directed toward the workspace through a plurality of micro-holes in a transparent diffuser separating the UV light source from the workspace.

14. The method of claim 13, wherein the UV light from the UV light source is directed toward the UV material layer of the workpiece through a bridge of UV transparent material disposed over the micro-holes of the diffuser.

15. The method of claim 13, wherein the inert gas is approximately uniformly distributed throughout the workspace through the micropores.

16. The method of claim 13, wherein the UV light is approximately uniformly distributed within the workspace through the micro-holes.

17. The method of claim 13, wherein the inert gas temperature is controlled to create a uniform reaction temperature.

18. The method of claim 13, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

19. The method of claim 11, wherein purging oxygen from the UV curing space comprises: during deposition of the layer of UV-curable material onto the workpiece, an inert gas is introduced through a diffuser into the UV-curing space within which the workpiece is located, the inert gas being introduced at a pressure sufficient to purge oxygen from an area adjacent to the diffuser.

20. The method of claim 19, further comprising: after curing the layer of UV-curable material, the workpiece is repositioned to deposit a next layer of UV-curable material and the inert gas pressure in the region adjacent to the diffuser is reduced.

Technical Field

The present invention relates to a system that prevents oxygen inhibition of photo-initiated polymerization reactions used by 3D printing systems by purging oxygen from the reaction surface using a flow of inert gas.

Background

Many additive manufacturing or so-called three-dimensional ("3D") printing, applications use ultraviolet ("UV") light curable polymers. The UV curing process consists of three stages: photoinitiation, propagation, and termination. During photoinitiation, the photoinitiator generates free radicals upon exposure to UV radiation. These radicals react with nearby monomers and convert them into radicals. Next, in the propagation stage, the free radical monomers bond with other monomers and convert those monomers into free radicals. In this way the monomers form polymer chains. This process continues until termination is reached. Termination can occur in a variety of ways, including free radical transfer to the monomer if the two chains are bonded to each other, or if the chains react with molecules from the environment, rather than with the monomer.

There are two interactions between oxygen and the photopolymer that inhibit curing: quenching and clearing. After the photoinitiator has been excited by exposure to UV radiation, it generates free radicals. Molecular oxygen readily reacts with this radical, preventing it from reacting with the monomer during chain extension. This is a quenching reaction. This reaction also produces oxygen radicals. In the scavenging reaction, this oxygen radical reacts with a radical that is part of the growing polymer chain. This reaction produces less reactive free radicals, which leads to premature termination of the polymerization process. These two processes can be written as:

quenching reaction: PI (proportional integral)^*+O₂ ^*→PI+O₂ ^*

And (3) clearing reaction: r + O₂ ^*→R-O-O·

Due to these phenomena, if the photopolymer is exposed to oxygen during curing in the 3D printing process, it may generate uncured polymer residues on the surface exposed to air.

Disclosure of Invention

In one embodiment of the invention, the UV curing system includes a gas diffusion system for introducing an inert gas into the working space between the UV light source and the UV curable layer of the workpiece. A transparent cover separates the UV light source from the working space, and an inert gas (e.g., Ar, CO)₂He, Ne, etc.) flows in from the gas inlet and out through the diffuser toward the workpiece. A gas pressure homogenizer is used to ensure a constant pressure throughout the system.

The diffuser is made of a transparent or diffusing material to allow UV light from the UV light source to pass through it. The diffuser includes a series of micro-holes for the inert gas to flow through to the workpiece. The small diameter of the holes allows them to be closely-packed in an arrangement such that the gas is uniformly distributed throughout the working space (i.e., throughout the curing zone). The small diameter of the holes also means that a larger area of the surface of the diffuser is free of holes so that its optical properties are more uniform. This ensures a relatively uniform light distribution. The holes are covered with "bridges" of UV transparent material from which the diffuser is made. This ensures that all light passing through the diffuser passes through at least a certain thickness of the transparent material, thereby further improving the light distribution.

After the UV curable material has been deposited on the surface of the workpiece and the workpiece is introduced into the work space of the UV curing system, an inert gas is pumped through a (pump through) diffuser. This flow of gas purges oxygen from the region of the workspace adjacent to the diffuser. The thickness of this region is related to the gas pressure as it is forced through the diffuser. After maintaining the workpiece in the region of the workspace from which oxygen has been purged, the UV curing system then cures the layer of UV curable material by exposure to light from the UV light source.

Another embodiment of the present invention provides oxygen inhibition to prevent photoinitiated polymerization by: periodically emitting UV light from a UV light source into a UV curing space in which a workpiece having a layer of UV curable material is disposed to promote UV curing of the UV curable material within the UV curing space and to purge oxygen from the UV curing space when the UV light source emits light onto the layer of UV curable material. Purging oxygen from the UV curing space includes: introducing an inert gas into a working space between a UV light source and the UV material layer of the workpiece through a gas diffusion system. For example, an inert gas may be introduced through one or more gas inlets of the gas diffusion system and flow to the workspace through a plurality of micro-holes in a transparent diffuser that separates the UV light source from the workspace. The UV light from the UV light source may flow through bridges of UV transparent material disposed over the micro-holes of the diffuser to the UV material layer of the workpiece. Thus, the inert gas and the UV light are each approximately uniformly distributed throughout the workspace through the micro-holes.

In some embodiments of the invention, the inert gas flow is used to uniformly heat the UV curable material during curing or to control the temperature of the UV curing space by controlling the inert gas temperature.

These and further embodiments of the present invention are described below with reference to the accompanying drawings, in which the invention is shown by way of example and not limitation.

Drawings

Fig. 1a to 1c show the gist in a conventional 3D printing process, wherein an object to be printed (fig. 1a) has deposited thereon a layer of UV-curable material (fig. 1b), which is subsequently cured by exposure to UV light (fig. 1 c).

Fig. 2 illustrates a UV curing system configured according to one embodiment of the present invention, wherein the inert gas flow is arranged to prevent oxygen inhibition of the polymerization process during UV curing.

Fig. 3a and 3b illustrate operational aspects of the UV curing system shown in fig. 2.

Fig. 4a and 4b show examples of UV light source and gas diffuser arrangements for the UV curing system as shown in fig. 2.

Fig. 5a and 5b illustrate aspects of a gas diffuser arrangement for the UV curing system shown in fig. 4.

Fig. 6a and 6b illustrate operational aspects of the UV curing system shown in fig. 2, in particular the sequence of printing, inert gas flow and UV curing process (fig. 6a) and the expansion of the oxygen-free layer (fig. 6 b).

Detailed Description

Before describing the present invention in detail, it is helpful to present an overview. Referring to the sequence of images shown in fig. 1a, 1b, and 1c, in many 3D printing processes in which an object 10 is being manufactured, a material printing system 12 is used to deposit a UV-curable material 14 on a surface 16. The deposited material is then cured with a UV light source 18 to produce a new layer of the desired portion 10'. This process continues until the portion being manufactured is completed.

Embodiments of the present invention provide systems and methods for preventing oxygen inhibition of photoinitiated polymerization reactions under ambient conditions. Referring now to fig. 2, in one embodiment of the present invention, a UV curing system 20 is provided with a gas diffusion system 22. A transparent cover 24 is disposed between the UV light source 26 and the gas diffusion system 22. Gas flows in from the gas inlet 28 and out through a diffuser 30 at the bottom of the system. The gas pressure homogenizer 32 is used to ensure a constant pressure throughout the system.

The diffuser 30 is made of a transparent or diffusing material to allow UV light to pass through it onto the workpiece 34, and in particular onto the UV curable material layer 36 disposed thereon. The diffuser 30 is comprised of a series of micro-holes 38. The small diameter of the micro-pores allows for a close packed arrangement thereof such that the gas is uniformly distributed throughout the curing zone 40. The small diameter of the pores 38 also means that a larger area of the surface of the diffuser 30 is free of pores, making its optical properties more uniform. This ensures a more uniform light distribution. Of course, other pore arrangements and sizes may be employed in order to optimize gas distribution and light distribution throughout the curing zone. The pores 38 are covered with "bridges" 42, the material of the "bridges" 42 being the material from which the diffuser is made. This ensures that all light passing through the diffuser must pass through a certain area of the transparent material. This further improves the light distribution.

Referring now to fig. 3a, after the UV curable material 36 has been deposited on the printing surface, gas is pumped through the diffuser 30 through the gas inlet 28. This flow of gas purges oxygen from the area 44 adjacent the diffuser 30. The thickness of this region is related to the gas pressure as it is forced through the diffuser. Thereafter, as shown in fig. 3(b), if necessary, the apparatus under fabrication is raised such that the UV curable material layer 36 disposed thereon is disposed within the oxygen free region 44, and the UV source 26 of the UV curing system 20 is activated, thereby curing at least a portion 36 'of the UV curable material layer 36' of the portion under fabrication in the region exposed to the UV light 48. In some cases, it will not be necessary to move the device under manufacture because the UV curable material layer 36 will already be within the oxygen free regions 44 as the gas is pumped through the diffuser 30. In embodiments of the invention, the gas pumped through the diffuser 30 is preferably an inert gas (e.g., Ar, CO)₂He, Ne, etc.) so long as it does not interact with the photopolymer in the UV curable layer 36 so as to inhibit its curing.

In some embodiments, the temperature of the feed gas may be controlled (e.g., by providing heating prior to the gas inlet 28 and/or within the gas diffusion system 22) to create a uniform reaction temperature at a location adjacent the workpiece 34 (e.g., within the space within which the layer of UV-curable material 36 disposed on the surface of the workpiece 34 is to be cured). For example, the inert gas may be heated prior to introduction into the gas diffusion system 22 in order to maintain a desired uniform reaction temperature within the surface location of the workpiece 34 adjacent to where the layer of UV-curable material 36 is disposed.

Fig. 4a and 4b show one example of a gas diffusion system 22. In fig. 4a, the front cover 50 is held in place (in place), while in fig. 4(b), the front cover 50 has been removed to show aspects of the interior of the gas diffusion system 22. In this example, gas diffusion system 22 is a right angle box with a UV light source 26 (e.g., comprised of one or more Light Emitting Diodes (LEDs)) mounted therein, inside the top of the box. The gas diffuser 30 forms the bottom surface of the tank. As mentioned above, the gas diffuser is made of a transparent material (at the illumination wavelength necessary to cure the photocurable material used to make the part in construction) to allow UV light from the source 26 to pass through relatively unattenuated.

Fig. 5a and 5b highlight the construction of the diffuser 30. As noted above, a bridge 42 (in the illustrated example, a rib shaped to run longitudinally across the upper surface of the diffuser 30) is provided above the gas flow holes 38 so that when the diffuser and UV light source are assembled in the gas diffusion system 22, they are in the light path between the UV light source 26 and the gas flow holes. This ensures that the UV light will pass through at least a certain thickness of the transparent material across the entire cured area. This ensures better light uniformity and more uniform curing of the photopolymer in the UV curable layer 36.

Returning to fig. 4b, gas enters the diffusion system 22 through one or more gas inlets 28 (e.g., by action of a pumping arrangement) and exits through the diffuser 30. A gas pressure homogenizer (not shown in this view) is used to ensure a constant pressure throughout the system.

Fig. 6a and 6b illustrate the cooperative operation employed during the printing and curing process. Printing (6a-10) of the next layer begins with the deposition of a layer of UV curable material on the printed surface of the object under manufacture. Towards the end of this deposition, gas is pumped 52 through the diffuser 30 via the gas inlet 28, as shown by the gas pressure curve in fig. 6 a. The gas pressure is increased to the level required for the curing process (6a-20) and oxygen is purged from the area 44 adjacent the diffuser 30. As shown by the oxygen-free region thickness curve in fig. 6a, the thickness (H) of this region increases with time and is related to the gas pressure as it is forced through the diffuser. When the desired thickness H has been reached, the apparatus under manufacture is raised (if necessary) so that the layer of UV-curable material disposed on the workpiece is within the oxygen-free region 44, and then the UV sources 26(6a-30) of the UV curing system 20 are activated, as shown by the UV source curves in fig. 6 a. This results in curing at least a portion of the layer of UV-curable material disposed on the workpiece in the region exposed to the UV light. At the end of curing (6a-40), the workpiece is repositioned to deposit the next layer of UV curable material and the gas pressure is reduced. Preferably, the gas pressure is maintained at a sufficient level to keep the diffusion system 22 full, so as to reduce the time required for the next curing cycle. When the desired number of layers has been cured, the process is complete.

The implementation scheme is as follows:

embodiment 1. a system for preventing oxygen inhibition of photoinitiated polymerization reactions at ambient conditions, said system comprising: an Ultraviolet (UV) light source; a UV curing space for receiving a workpiece having a layer of UV curable material; and means for scavenging oxygen from the UV curing space to facilitate UV curing of the UV curable material within the UV curing space when the UV light source emits light onto the layer of UV curable material.

Embodiment 2. the system of embodiment 1, wherein the means for scavenging oxygen comprises: a gas diffusion system for introducing an inert gas into a working space between the UV light source and the UV material layer of the workpiece; and a transparent cover separating the UV light source from the workspace, wherein the gas diffusion system and the transparent cover are arranged relative to each other so as to allow inert gas flowing in from one or more gas inlets of the gas diffusion system to flow out through a diffuser towards the workspace.

Embodiment 3. the system of any of the preceding embodiments, wherein the diffuser has a plurality of micro-holes with bridges of UV transparent material disposed over the micro-holes so as to be positioned between respective inlets of the micro-holes and the UV light source.

Embodiment 4. the system of any of the preceding embodiments, further comprising a gas pressure homogenizer for ensuring a constant pressure throughout the system.

Embodiment 5. the system of any of the preceding embodiments, wherein the diffuser is made of the UV transparent material to allow UV light from the UV light source to pass through it.

Embodiment 6. the system of any of the preceding embodiments, wherein the micro-pores are sized and spaced relative to each other so as to optimize gas distribution and UV light distribution throughout the workspace.

Embodiment 7. the system of any of the preceding embodiments, wherein the microwells are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the working space and are equal in size such that UV light is approximately uniformly distributed within the working space.

Embodiment 8 the system of any of the preceding embodiments, wherein the microwells are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the workspace and UV light is approximately uniformly distributed within the workspace.

Embodiment 9. the system of any of the preceding embodiments, wherein the temperature of the inert gas is controlled to create a uniform reaction temperature.

Embodiment 10. the system of any of the preceding embodiments, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

Embodiment 11. a method for preventing oxygen inhibition of photoinitiated polymerization under ambient conditions, said method comprising: periodically emitting Ultraviolet (UV) light from a UV light source into a UV curing space in which a workpiece having a layer of UV curable material is disposed to promote UV curing of the UV curable material within the UV curing space and to purge oxygen from the UV curing space when the UV light source emits light onto the layer of UV curable material.

Embodiment 12 the method of embodiment 11, wherein purging oxygen from the UV curing space comprises: introducing an inert gas into a working space between a UV light source and the UV material layer of the workpiece through a gas diffusion system.

Embodiment 13 the method of embodiment 11 or 12, wherein the inert gas is introduced through one or more gas inlets of the gas diffusion system and directed toward the workspace through a plurality of micro-holes in a transparent diffuser separating the UV light source from the workspace.

Embodiment 14 the method of any one of embodiments 11 to 13, wherein the UV light from the UV light source is directed toward the UV material layer of the workpiece through a bridge of UV transparent material disposed over the pores of the diffuser.

Embodiment 15 the method of any one of embodiments 11 to 14, wherein the inert gas is approximately uniformly distributed throughout the working space through the micropores.

Embodiment 16 the method of any one of embodiments 11 to 15, wherein the UV light is approximately uniformly distributed within the workspace through the microwells.

Embodiment 17 the method of any one of embodiments 11 to 16, wherein the inert gas temperature is controlled to create a uniform reaction temperature.

Embodiment 18 the method of any one of embodiments 11 to 17, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

Embodiment 19 the method of any one of embodiments 11 to 18, wherein purging oxygen from the UV curing space comprises: during deposition of the layer of UV-curable material onto the workpiece, an inert gas is introduced through a diffuser into the UV-curing space within which the workpiece is located, the inert gas being introduced at a pressure sufficient to purge oxygen from an area adjacent to the diffuser.

Embodiment 20. the method of one of embodiments 11 or 19, further comprising: after curing the layer of UV-curable material, the workpiece is repositioned to deposit a next layer of UV-curable material and the inert gas pressure in the region adjacent to the diffuser is reduced.

Thus, a system for preventing oxygen inhibition of photoinitiated polymerization reactions by scavenging oxygen from the reaction surface using a flow of inert gas has been described.

The claims (modification according to treaty clause 19)

1. A system for preventing oxygen inhibition of photoinitiated polymerization reactions under ambient conditions for use in a 3D printing system, the system comprising: an Ultraviolet (UV) light source; a UV curing space for receiving a workpiece having a layer of UV curable material; and means for scavenging oxygen from the UV curing space to facilitate UV curing of the UV curable material within the UV curing space when the UV light source emits light onto the layer of UV curable material, wherein the means for scavenging oxygen comprises: a gas diffusion system for introducing an inert gas into a working space between the UV light source and the UV curable material layer of the workpiece; and a transparent cover separating the UV light source from the working space, wherein the gas diffusion system and the transparent cover are arranged relative to each other so as to allow an inert gas flowing in from one or more gas inlets of the gas diffusion system to flow out through the diffuser towards the working space, and wherein the diffuser has a plurality of micro-holes with bridges of UV transparent material arranged over the micro-holes so as to be positioned between respective inlets of the micro-holes and the transparent cover.

2. The system of claim 1, further comprising a gas pressure homogenizer to ensure a constant pressure throughout the system.

3. The system of claim 1, wherein the diffuser is made of the UV transparent material to allow UV light from the UV light source to pass through it.

4. The system of claim 1, wherein the micro-holes are sized and spaced relative to each other so as to optimize gas distribution and UV light distribution throughout the workspace.

5. The system of claim 4, wherein the micro-pores are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the workspace and are equal in size such that UV light is approximately uniformly distributed within the workspace.

6. The system of claim 1, wherein the micro-pores are spaced relative to each other in an array such that the gas is approximately uniformly distributed throughout the workspace and UV light is approximately uniformly distributed within the workspace.

7. The system of claim 1, wherein the temperature of the inert gas is controlled to create a uniform reaction temperature.

8. The system of claim 1, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

9. A method for use by a 3D printing system for preventing oxygen inhibition of photoinitiated polymerization reactions under ambient conditions, the method comprising: periodically emitting Ultraviolet (UV) light from a UV light source into a UV curing space in which a workpiece having a layer of UV curable photopolymer is disposed to promote UV curing of the UV curable photopolymer within the UV curing space and to purge oxygen from the UV curing space when the UV light source emits light onto the UV curable photopolymer layer.

10. The method of claim 9, wherein purging oxygen from the UV curing space comprises: introducing an inert gas into a working space between a UV light source and the UV curable photopolymer layer of the workpiece through a gas diffusion system.

11. The method of claim 10, wherein the inert gas is introduced through one or more gas inlets of the gas diffusion system and directed toward the workspace through a plurality of micro-holes in a transparent diffuser separating the UV light source from the workspace.

12. The method of claim 11, wherein the UV light from the UV light source is directed toward the UV curable photopolymer layer of the workpiece through a bridge of UV transparent material disposed over the micro-holes of the diffuser.

13. The method of claim 11, wherein the inert gas is approximately uniformly distributed throughout the workspace through the micropores.

14. The method of claim 11, wherein the UV light is approximately uniformly distributed within the workspace through the micro-holes.

15. The method of claim 11, wherein the inert gas temperature is controlled to create a uniform reaction temperature.

16. The method of claim 11, wherein the inert gas is heated to maintain a desired and uniform reaction temperature.

17. The method of claim 9, wherein purging oxygen from the UV curing space comprises: during deposition of the UV-curable photopolymer layer onto the workpiece, an inert gas is introduced into the UV-curing space within which the workpiece is located through a diffuser, the inert gas being introduced at a pressure sufficient to purge oxygen from the area adjacent to the diffuser.

18. The method of claim 17, further comprising: after curing the layer of UV-curable material, the workpiece is repositioned to deposit the next layer of UV-curable photopolymer and the inert gas pressure in the area adjacent to the diffuser is reduced.