阅读说明：本技术 3d打印机的流体供应系统 (Fluid supply system of 3D printer ) 是由 米里亚姆·赫斯特 斯特凡·莱茵哈特 斯特凡·费舍尔 塞巴斯蒂安·帕默 于 2018-09-28 设计创作，主要内容包括：本发明涉及一种用于至少一个3D打印机(12),特别是FFF 3D打印机(12)的流体供应系统(10),该流体供应系统(10)具有至少一个用于产生加压流体流(16)的流体压力产生装置(14),且具有至少一个用于加热流体流(16)的流体加热装置(18),其中3D打印机(12)具有至少一个构造室(20),该构造室(20)由至少一个构造室壳体(22)相对于3D打印机(12)的周围环境界定,并以流体密封的方式密封,其中流体压力产生装置(14)、流体加热装置(18)和构造室壳体(22)流体连通,从而流体流(16)可以流过构造室(20),并且其中流体压力产生装置(14)、流体加热装置(18)和构造室壳体(22)界定流体流(16)的封闭的流体回路(24),流体流(16)在进入构造室(20)之前通过流体加热装置(18)加热。(The invention relates to a fluid supply system (10) for at least one 3D printer (12), in particular an FFF 3D printer (12), the fluid supply system (10) having at least one fluid pressure generating device (14) for generating a pressurized fluid flow (16) and having at least one fluid heating device (18) for heating the fluid flow (16), wherein the 3D printer (12) has at least one build chamber (20), which build chamber (20) is delimited by at least one build chamber housing (22) with respect to the surroundings of the 3D printer (12) and is sealed in a fluid-tight manner, wherein the fluid pressure generating device (14), the fluid heating device (18) and the build chamber housing (22) are in fluid communication such that the fluid flow (16) can flow through the build chamber (20), and wherein the fluid pressure generating device (14) has a fluid inlet and a fluid outlet, and wherein the fluid pressure generating device (14) has a fluid outlet, and wherein the fluid outlet is sealed in a, The fluid heating device (18) and the build chamber housing (22) define a closed fluid circuit (24) for the fluid flow (16), the fluid flow (16) being heated by the fluid heating device (18) prior to entering the build chamber (20).)

1. A fluid supply system (10) for at least one 3D printer (12), in particular an FFF 3D printer (12), the fluid supply system (10) having at least one fluid pressure generating device (14) for generating a pressurized fluid flow (16) and having at least one fluid heating device (18) for heating the fluid flow (16), wherein the 3D printer (12) has at least one build chamber (20), the build chamber (20) being delimited with respect to the surroundings of the 3D printer (12) by at least one build chamber housing (22) and sealed in a fluid-tight manner, wherein the fluid pressure generating device (14), the fluid heating device (18) and the build chamber housing (22) are in fluid communication such that the fluid flow (16) can flow through the build chamber (20), and wherein the fluid pressure generating device (14), the fluid heating device (18) and the build chamber housing (22) form a closed fluid circuit (24) of the fluid flow (16) which is heated by the fluid heating device (18) before entering the build chamber (20).

2. The fluid supply system (10) according to claim 1, characterized in that the fluid supply system (10) in an operating state is designed such that the fluid flow (16) can flow through the build chamber (20) in the structure in a substantially laminar flow.

3. The fluid supply system (10) according to claim 2, characterized in that the 3D printer (12) comprises at least one print head (26), which print head (26) is movable in multiple axes and/or dimensions, in particular in a three-dimensional manner, within the build chamber (20), and at least one build platform (28) which is surrounded by a laminar flow of the fluid flow (16).

4. The fluid supply system (10) according to claim 2 or claim 3, wherein the fluid supply system (10) comprises at least one build chamber inlet region (30) arranged upstream of the build chamber housing (22) and wherein at least one flow direction unit (32) is arranged.

5. The fluid supply system (10) according to claim 4, characterized in that the flow direction unit (32) comprises a flow guiding structure (34), in particular a flow guiding body (36), for at least partially stratigraphically orienting the fluid flow (16).

6. The fluid supply system (10) according to any one of the preceding claims, wherein the fluid supply system (10) comprises at least one fluid sterilization and/or fluid filtration device (38) in fluid connection with the pressure generating device (14), the fluid heating device (18) and the construction chamber housing (22).

7. The fluid supply system (10) according to claim 1, characterized in that the temperature of the fluid stream (16) is in particular in the range of about 20 ℃ to about 400 ℃, preferably in the range of about 30 ℃ to about 350 ℃, particularly preferably in the range of about 50 ℃ to about 300 ℃.

8. The fluid supply system (10) according to claim 1, characterized in that the velocity, in particular the average velocity, of the fluid flow (16) within the build chamber (20) is in particular in the range of about 0.05m/s to about 5m/s, preferably in the range of about 0.1m/s to about 5m/s, particularly preferably in the range of about 0.2m/s to about 3 m/s.

9. The fluid supply system (10) of claim 5, wherein the fluid sterilization and/or fluid filtration device (38), the fluid pressure generating device (14), the fluid heating device (18), and/or the build chamber housing (22) are heat resistant at temperatures up to about 300 ℃.

10. The fluid supply system (10) according to claim 1, characterized in that the fluid pressure generating device (14) is a flow machine such as a turbo compressor (40), in particular a radial compressor (40) or a ventilator.

11. The fluid supply system (10) according to claim 10, characterized in that at least one pressure reduction device (42) is arranged downstream of the flow machine (40).

12. The fluid supply system (10) according to claim 11, wherein the pressure reduction device (42), the fluid sterilization and/or filtration device (38), the fluid heating device (18) and/or the flow direction unit (32) are capable of at least reducing the pressure of the fluid flow by at least 50 Pa.

13. The fluid supply system (10) according to any one of claims 4 to 12, characterized in that the fluid supply system (10) comprises a particle measuring device (44), the particle measuring device (44) being provided for monitoring the operation of the 3D printer (12) and being arranged in a build chamber inlet region (30) between a flow orientation unit (32) and at least one inlet of a build chamber housing (22).

14. The fluid supply system (10) according to any one of the preceding claims, characterized in that the fluid flow (16) comprises a fluid, which is a gas, in particular air.

15. The fluid supply system (10) according to any one of the preceding claims, characterized in that the fluid supply system (10) has at least one gas connection (46), by means of which gas connection (46) the fluid supply system (10) can be filled with at least one process gas other than air when the 3D printer (12) is not in operation during filling.

Technical Field

The invention relates to a fluid supply system for at least one 3D printer, having at least one fluid pressure generating device for generating a pressurized fluid flow and at least one fluid heating device for heating the fluid flow.

Background

In connection with 3D printing of plastics, particularly for medical applications (e.g. implants), the component quality currently achievable is the focus of much scientific research. The two most important challenges that are decisive in terms of the quality of the components are the tolerances of the components and the sterility of the components or the precipitation of particles.

For example, DE 102015111504 a1 discloses A3D printing device, in particular an FFF printing device, having at least one printhead unit, wherein the printhead unit is intended to be in at least one operating state to melt a printing material, in particular a high-performance thermoplastic material, which is at least partially formed from a high-performance plastic material.

Furthermore, EP 2261009 a1 discloses an apparatus and a method for manufacturing a three-dimensional object, wherein the apparatus comprises a vacuum pump coupled to a feed container to generate an air flow through the feed container.

In addition, EP 3023228 a1 shows an additive manufacturing apparatus with a gas flow system for providing a gas flow over the area of a build platform of the additive manufacturing apparatus.

Furthermore, EP 3173233 a1 discloses a three-dimensional production device having a process space which is heated by a process space heating unit provided for this purpose.

Further, US 6,033,301 a discloses a combined fan filter unit arranged for filtering air of an air circuit in a clean room.

Furthermore, US 6,722,872B 1 shows a three-dimensional modeling apparatus intended to build up three-dimensional objects inside a heated build chamber.

Further, US 6,817,941B 1 shows a diffuser for generating a uniform air flow in the process chamber used, which is used in the production of, for example, semiconductor chips.

Furthermore, US 2015/110911 a1 shows an environmental monitoring and control unit, for example for use in additive manufacturing techniques, as an interface to its respective environment.

Furthermore, WO 2016/063198 a1 shows a method and an apparatus for producing three-dimensional objects by "fused deposition modeling", wherein the production apparatus comprises a radiant heating element which is capable of heating the surface of the object to be produced exposed thereto. In addition, clean room technology for 3D printers and so-called bioprinters is known from WO 2017/040675 a 1.

From WO 2017/108477 a1, a method for producing three-dimensional objects using a "fused deposition modeling" printer can also be found.

Based on the solutions proposed in the prior art, these additive manufacturing devices still have the problems of high component distortion, insufficient sterility and insufficient degree of lack of germs and particles thereof for medical applications. The goal is to minimize contamination of the components, which is not currently achieved.

The object of the present invention is therefore to further develop a fluid supply system for a 3D printer of the type described above in an advantageous manner, in particular with regard to improving the distortion and sterility of components produced by means of the 3D printer, and to increase the energy efficiency of the fluid supply system.

Disclosure of Invention

According to the invention, this object is achieved by a fluid supply system for a 3D printer having the features of claim 1. Accordingly, a fluid supply system for at least one 3D printer, in particular an FFF 3D printer, is provided having at least one fluid pressure generating device for generating a pressurized fluid flow and at least one fluid heating device for heating the fluid flow, wherein the 3D printer has at least one build chamber which is defined by at least one build chamber housing relative to the surroundings of the 3D printer and is sealed in a fluid-tight manner, wherein the fluid pressure generating device, the fluid heating device and the build chamber housing are fluidically connected such that a fluid flow can flow through the build chamber, and wherein the fluid pressure generating device, the fluid heating device and the build chamber housing delimit a closed fluid circuit for the fluid flow, the fluid flow being heated by the fluid heating device before entering the build chamber.

A valve or inflow of ambient air that is advantageously filtered may also be provided to regulate the build chamber. In principle, it can be provided that even an air gap or an air inflow of outside air can be present or allowed. Complete liquid tightness is not required. Furthermore, even after the pressure has built up, an additional supply of cold air can be mixed into the heated circuit to cool the build chamber.

The invention is based on the following basic idea: due to the configuration of the closed fluid circuit, fluid that has flowed through the build chamber of the 3D printer and has been heated before it enters, after it leaves, is not released from the build chamber into the environment of the 3D printer and is not used. Instead, the partially heated fluid exiting the build chamber may return to the build chamber due to the closed fluid circuit. This type of fluid circuit is particularly advantageous because the fluid leaving the build chamber still has a significantly higher temperature than the ambient temperature. As a result, the energy provided to reheat the fluid can be significantly reduced. On the one hand, the energy required for heating the fluid can be greatly reduced. On the other hand, since the fluid heating device does not have to heat the fluid from the ambient temperature to the desired build chamber temperature, it can be dimensioned to save more space and be more compact than in the prior art. Heating of the build chamber is particularly desirable for low distortion processing of semi-crystalline thermoplastics. The at least partial heating of the construction chamber by the upstream heated fluid flow allows a particularly uniform temperature distribution to be achieved within the construction chamber. This uniform temperature distribution has an additional positive effect on the reduction of distortion during processing of thermoplastics. In summary, the fluid supply system can thus be designed to be more efficient and economical. Furthermore, since the already filtered air stream is continuously circulated and the air stream is filtered again, there is no longer a need to filter out particles from the ambient air. As a result, less particles need to be filtered out of the air flow in total, which is why the filter can also achieve a longer service life.

Furthermore, it can be provided that the fluid supply system in its operating state is designed such that the fluid flow can flow through the build chamber in a substantially laminar flow. Laminar flow through the build chamber (with laminar air flow, in particular for creating clean room conditions) has advantages, in particular due to its directional flow characteristics (non-cross flow), such that contamination of the build chamber by particles or germs contained in or carried by the fluid is reduced as much as possible. Since the invention is also used in the field of medical technology (for example, for producing implants), the lowest possible contamination of the component to be produced has a particularly positive effect on its sterility. In this case, it is also conceivable that the fluid flow may flow through the build chamber in a substantially vertical laminar flow.

It is also conceivable that the 3D printer comprises at least one print head which can be moved in a multi-axis and/or multi-dimensional, in particular three-dimensional, manner within the build chamber, and at least one build platform which is surrounded by a laminar flow of the fluid stream. The three-dimensionally movable print head and the laminar flow of fluid flow around the print head and build platform make it possible to print the product to be produced in a laminar air flow, which is advantageous for sterility and sterilization and for particle protection. Laminar flow around these components particularly reduces contamination or deposition due to particles or pathogens present in the air. Since these two components are in direct contact with the part to be manufactured, their sterile, particle-free and dust-free surfaces are of critical importance.

It is also conceivable that the fluid supply system comprises at least one build chamber inlet region which is arranged upstream of the build chamber housing and in which the at least one flow direction unit is arranged. The flow direction unit is advantageously used to calm the fluid flow before it enters the build chamber. Since the fluid flow upstream of the flow direction unit is swirled by the fluid pressure generating means, the fluid heating means and by the ducts and elbows, the fluid flow must be directed before entering the build chamber. It is particularly advantageous to design the chamber inlet region in the form of a diffuser. One possible geometric design of the diffuser may be a thin-walled hollow cone whose cross-sectional area in relation to the flow increases linearly upstream towards the build chamber.

Furthermore, it is possible that the flow direction unit comprises a flow directing structure, in particular a flow directing body, for directing the fluid flow at least partially in the formation. Such a flow guiding structure is a component which is integrated into the overall device and enables a targeted and particularly effective laminar flow orientation of the fluid flow and can therefore be advantageously arranged in the region of the build chamber inlet. The flow guiding structure allows to guide the fluid flow in such a way that a desired laminar flow can be achieved in the region of the build chamber inlet. The flow guide may comprise, for example, a diffuser. In this case, for example, it is conceivable to design the diffuser as a thin-walled hollow cone, the side faces of which are shaped in such a way that the hollow cone widens in the direction of the build chamber.

Furthermore, the flow direction unit may be designed in such a way that an air curtain is formed around the component and thus the component is not directly exposed to the flow. This makes it possible to reduce component distortion. This is achieved in particular by the fact that no direct air flow hits the component, so that the component cools uniformly.

In addition, the fluid supply system may comprise at least one fluid sterilization and/or filtration device in fluid connection with the fluid pressure generating device, the fluid heating device and the build chamber housing. Thanks to the fluid sterilization and/or filtration device, the fluid supplied to the construction chamber can be filtered and/or cleaned in a particularly efficient manner. The fluid sterilization and/or filtration device is located upstream (relative to the direction of flow through the build chamber). By proper design of this device, fluids before entering the build chamber can be cleaned, sterilized and filtered to conform the build chamber to the specifications and standards of EN ISO 14644 clean room. In this case, a closed fluid circuit is particularly advantageous. This is because the continuous circulation of fluid within the fluid supply system involves returning cleaned or filtered fluid from the first circulation to the fluid sterilization and/or filtration device. As a result, the filtration and/or sterilization of the fluid can be carried out in each cycle of the fluid, which has a decisive effect on the sterility and particle contamination of the components to be produced.

It is also conceivable that the temperature of the fluid stream ranges in particular from about 20 ℃ to about 400 ℃, preferably from about 30 ℃ to about 350 ℃, particularly preferably from about 50 ℃ to about 300 ℃. The above temperature range, in particular a temperature range of about 50 ℃ to about 300 ℃, is particularly advantageous for producing thermoplastics with as little distortion as possible using a 3D printer. For example, the thermoplastic may be selected from high performance thermoplastics. The high-performance thermoplastic may be polyetherketones (e.g. PAEK, PEKK, PEEK, PEEEK, PEEKK, PEKK), polyamides (e.g. PA 69, PA 612, PA 11, PA 12, PA 46, PA 1212, PA 6/12, PA 1010, PPA), polyphenylene sulfide PPS, polyamideimides, polysulfones (e.g. PAs, PSF, PES, PPSU, PSU, PESU) and/or polycarbonate PC and thermoplastic polyimides (PEI, PAI, PESI). It is also conceivable that the thermoplastic is reinforced with fibers and/or particles.

Furthermore, it is conceivable that the fluid flow has a velocity, in particular an average velocity, in particular in the range from about 0.05m/s to about 5m/s, preferably in the range from about 0.1m/s to about 5m/s, particularly preferably from about 0.2m/s to about 3m/s, within the construction chamber. The above-mentioned range of the average velocity of the fluid flow, in particular the velocity range from about 0.2m/s to about 3m/s, may ensure a reliable, in particular constant and uniform heating of the build chamber of the 3D printer. Most importantly, this type of heating helps to significantly reduce component distortion when processing thermoplastics. Incidentally, a fluid flowing through the build chamber is required to meet the above criteria.

Furthermore, the fluid sterilization and/or filtration device, the fluid pressure generating device, the fluid heating device, and/or the construction chamber housing may be high temperature resistant, up to a maximum temperature of about 300 ℃. The maximum temperature of the fluid is up to about 300 ℃, and substantially all related art thermoplastics can be processed through a 3D printer. Thus, a maximum temperature of about 300 ℃ is particularly effective, advantageous and necessary for distortion-free processing of thermoplastics.

Furthermore, it can be provided that the fluid pressure generating device is a flow machine such as a turbocompressor, in particular a radial compressor, or a fan or a centrifugal fan. Basically, the flow machine is, for example, a fan or a compressor. This type of compressor produces particularly low pulsations or low impacts and therefore a constant flow of pressurized fluid, so that pressure and temperature fluctuations inside the construction chamber can also be minimized. As a result, a more uniform temperature distribution can be achieved within the build chamber. In particular, the radial compressor can also be designed as a radial fan resistant to high temperatures up to about 300 ℃.

It is also conceivable for at least one pressure reduction device to be arranged downstream of the turbocompressor. The pressure reduction device can be used in a particularly advantageous manner, since it generates a certain back pressure for the turbo compressor, which for physical reasons has to use a centrifugal fan or blower with a temperature resistance of up to 300 ℃. The pressure reduction means can be designed, for example, as a perforated plate or a perforated membrane.

It is also conceivable that the pressure reduction device, the fluid sterilization and/or filtration device, the fluid heating device and/or the flow direction unit are capable of generating a fluid flow pressure reduction of at least 50 Pa. The pressure reduction caused by the above-mentioned components has a particularly advantageous effect on the operation or controllability and/or adjustability of the turbocompressor, in particular of the temperature-resistant radial compressor. Furthermore, in the presence of such pressure losses, a radial compressor dimensioned for a 3D printer can be operated particularly efficiently and advantageously.

Furthermore, the fluid supply system may comprise a particle measurement device provided for monitoring the operation of the 3D printer and arranged in a build chamber inlet region between the flow direction unit and the at least one inlet opening of the build chamber housing. Such particle measuring devices are particularly important and advantageous for achieving high composition standards in terms of sterility and particle contamination, which is particularly desirable in medical technology. Since maintenance or replacement of the fluid sterilization and/or filtration device can be recommended on the basis of the particle measurement, by using the particle measurement device it is also possible to optimize the monitoring of the entire fluid supply system of the 3D printer, for example by means of a central electronic control and/or regulation unit of the 3D printer. Furthermore, based on particle measurements, the 3D printing process may also be aborted if a certain limit value of particles in the fluid flow is exceeded. It is also contemplated that the fluid sterilization and/or filtration device may be bypassed by a bypass valve and a bypass line based on particulate measurements. In this way, the bypass valve can open the bypass line until the adjustable limit for particulates in the fluid flow is exceeded. In particular when very expensive fluid sterilization and/or filtration equipment is used, the bypass line can lead to a significant increase in its service life and extended maintenance intervals.

Furthermore, it can be provided that the fluid flow contains a fluid as a gas, in particular air. The use of gases, in particular air, is particularly advantageous because of the virtually unlimited availability of air and is therefore very easy to handle.

It is also conceivable that the fluid supply system has at least one gas connection, by means of which the fluid supply system can be filled with at least one process gas other than air, and that the 3D printer is not operated during filling. In this case, it is conceivable that the process gas is an inert gas. In particular, when the 3D printer processes thermoplastics that are susceptible to oxidation, the use of inert gas may prevent oxidation, so that the part quality may be further improved.

Drawings

Further details and advantages of the invention will now be explained in detail by means of embodiments shown in the drawings, in which:

fig. 1 is a schematic diagram of an exemplary embodiment of a fluid supply system for a 3D printer according to the present invention.

Fig. 2 is a partial cross-sectional view of a flow conductor disposed therein and a chamber inlet region configured according to the fluid supply system of fig. 1.

FIG. 3 is a schematic perspective view of a receiving frame for the 3D printer and fluid supply system of FIG. 1; and

fig. 4 is a schematic front view of a build chamber of the 3D printer according to fig. 1.

Description of reference numerals:

10 fluid supply system

123D printer

14 fluid pressure generating device

16 flow of fluid

18 fluid heating device, flow heater

20 structure chamber

22 construction chamber housing

24 fluid circuit

26 printhead

28 construction platform

30 configuration of the Chamber Inlet region

32 flow direction unit

34 flow guiding structure

36 flow guide body

38 fluid sterilization and filtration device

40 radial compressor

42 pressure reducing device

44 particle measuring device

46 gas joint

48 pipe system

50 diffuser

52 semicircular top

54 rotating body

56 receiving frame

58 profile support

60 frame

62 Linear guide

64 sliding rack

66 step motor

Detailed Description

Fig. 1 shows a schematic view of an exemplary embodiment of a fluid supply system 10 for a 3D printer 12 according to the present invention.

For example, a 3D printer 12 including a trigonometric motion system or a cartesian system may be used as the 3D printer 12. In principle, the 3D printer 12 may also be a multi-dimensional printer and/or a printer with multiple axes.

The 3D printer 12 is designed as an FFF 3D printer (FFF: Fused fiber fabrication).

The fluid supply system 10 includes a fluid pressure generating device 14 for generating a pressurized fluid stream 16.

The fluid stream 16 contains the fluid as a gas.

The gas may be air or a process gas such as an inert gas.

Furthermore, the fluid supply system 10 comprises a fluid heating device 18 for heating the fluid flow 16.

The 3D printer 12 also has a build chamber 20, the build chamber 20 being fluidly confined and sealed from the environment of the 3D printer 12 by a build chamber housing 22.

In addition, the fluid pressure generating device 14, the fluid heating device 18, and the build chamber housing 22 are in fluid communication.

Thus, fluid flow 16 may flow through build chamber 20.

Inside the build chamber 20, the fluid stream 16 has an average velocity in the range of about 0.2m/s to about 3 m/s.

The fluid stream 16 may also have an average velocity within the build chamber 20 in a range of about 0.05m/s to about 5 m/s.

Additionally, it is contemplated that the average velocity of the fluid flow 16 within the build chamber 20 may be in the range of about 0.1m/s to about 5 m/s.

Furthermore, the fluid pressure generating device 14, the fluid heating device 18 and the build chamber housing 22 form a closed fluid circuit 24 for the fluid flow 16.

In particular, the fluid stream 16 has a temperature in the range of about 50 ℃ to about 300 ℃.

However, it is also contemplated that the temperature of fluid stream 16 may be in the range of about 20 ℃ to about 400 ℃.

It is also contemplated that the temperature of fluid stream 16 may be in the range of about 30 ℃ to about 350 ℃.

The fluid flow 16 has these temperature ranges, particularly inside the build chamber 20.

The fluid stream 16 is also heated by the fluid heating device 18 prior to entering the build chamber 20.

The 3D printer 12 also has a print head 26, which print head 26 can move along multiple axes within the build chamber 20, and a build platform 28.

When 3D printer 12 is ready to operate, printhead 26 and build platform 28 are surrounded by a laminar flow of fluid stream 16.

The fluid supply system 10 also has a build chamber inlet region 30.

The build chamber inlet region 30 is located upstream of the build chamber housing 22.

A flow direction cell 32 is located within the build chamber inlet region 30.

The flow direction unit 32 comprises a flow directing structure 34.

The flow directing structure is designed as a flow directing body 36.

The fluid supply system 10 according to fig. 1 further comprises a fluid sterilization and filtration device 38.

The fluid sterilization and filtration device 38 is in fluid connection with the fluid pressure generating device 14, the fluid heating device 18, and the build chamber housing 22.

Further, the fluid pressure generating device 14 is a radial compressor 40.

The pressure reduction device 42 is located downstream (relative to the direction of fluid flow through the device) of the radial compressor 40.

The fluid supply system 10 also has a particle measurement device 44 for monitoring the operation of the 3D printer 12.

The particle measurement device 44 is located in the build chamber inlet region 30 between the flow direction unit 32 and the inlet of the build chamber housing 22.

Furthermore, the fluid supply system 10 has a gas connection 46.

The fluid supply system 10 shown in fig. 1 also includes a piping system 48 that forms the closed fluid circuit 24.

The piping 48 is composed of several straight pipe sections and 90 ° bends, the radial compressor 40, the fluid heating device 18, the fluid sterilization and filtration device 38, the build chamber inlet area 30 and the build chamber 20 communicating with each other through the piping 48.

The radial compressor 40 is flanged to the build chamber housing 22 at the build chamber outlet, while the build chamber inlet region 30 is flanged to the build chamber housing 22 at the build chamber inlet.

Between the radial compressor 40 and the build chamber inlet area 30, the fluid heating device 18 and the fluid sterilizing filter device 38 are arranged in a piping system 48.

The fluid heating device 18 is located downstream of the radial compressor 40.

The fluid sterilization and filtration device 38 is located downstream of the fluid heating device 18 in the piping system 48.

The fluid heating device 18 is designed as a flow heater with an electrical heating element, which may be in the form of a heating coil, for example.

The fluid sterilization and filtration device 38 may have, for example, an EPA, HEPA or U L PA filtration unit.

Fluid sterilization and filtration device 38 may also have separation efficiencies according to filter grades E10, E11, E12, H13, H14, U15, U16, or U17.

The function of the fluid supply system 10 can now be described as follows:

before starting up the 3D printer 12, the fluid supply system 10 should first check whether gas and printing material suitable for the printing process are contained in the build chamber 20.

This check may be accomplished, for example, by a gas sensor located within the piping system 48 or in the build chamber 20 and capable of determining the appropriate gas.

Determining different gases may also require the use of multiple gas sensors.

Air as the process gas may be filled into the fluid supply system 10 (after previously used gases are evacuated), for example, through supply and exhaust valves located inside the piping system 48.

The radial compressor 40 may be used to support or accelerate the air filling process.

The 3D printer 12 does not operate during the filling process.

After filling the fluid supply system 10, the fluid supply system 10 is sealed from the surrounding atmosphere by closing the supply and exhaust valves (not shown in fig. 1).

Even before the 3D printer 12 is operated, air inside the fluid supply system 10 may be circulated by the radial compressor 40, thereby achieving pre-cleaning of the air.

During the pre-cleaning process, the fluid heating device 18 may already be in operation, which additionally pre-heats the build chamber 20.

Once the build chamber 20 has a build chamber temperature suitable for the material and part to be produced, the 3D printer 12 begins operation.

During operation of the 3D printer 12, air leaving the build chamber 20 is drawn in by the radial compressor 40, compressed and then supplied to the fluid heating device 18.

Where the air is heated to an adjustable or controllable temperature value and, after flowing out of the fluid heating device 18, is sent to a fluid sterilization and filtration device 38 where it is cleaned and filtered. It then flows downstream into the build chamber inlet region 30.

In particular, the fluid sterilization and filtration device 38, the fluid pressure generating device 14 in the form of a radial compressor 40, the fluid heating device 18 and the build chamber housing 22 are high temperature resistant, up to a maximum temperature of about 300 ℃. However, normal applications may also require lower maximum temperatures, in the range of 150-.

During the flow through the build chamber inlet region 30, the housing of which is designed as a diffuser and in which the flow guide body 36 is arranged, a laminar orientation of the fluid flow 16 will be formed.

Thus, the flow guide 36 serves at least in part for laminar orientation of the fluid flow 16.

However, the diffuser also serves for laminar orientation of the fluid flow 16.

Thus, in a state ready for operation, the fluid supply system 10 is designed such that the fluid flow 16 can flow through the build chamber 20 in a laminar flow.

The particle measuring device 44 can also measure the number of particles in the build chamber inlet region 30 before the air enters the build chamber 20 and provide it as a measured variable to the electronic control unit.

A control unit (not shown in fig. 1) is used to control the radial compressor 40 and the drive system (e.g. electric motor) of the fluid heating device 18.

The control unit may be integrated into the fluid supply system 10 or arranged on the build chamber housing 22.

Furthermore, the control unit is electrically connected to all sensors located in the fluid supply system 10 and the build chamber housing 20.

The fluid supply system 10 and the 3D printer 12 may therefore have one or more pressure and temperature sensors.

Between the build chamber inlet region 30 and the build chamber housing 22, a pressure relief device 42 (for example in the form of a perforated plate) can be arranged, which at least partially generates the back pressure necessary for the operation of the radial compressor 40.

The back pressure is necessary to prevent the radial compressor 40 from "running up" indefinitely, i.e., to avoid an unlimited increase in the speed of the radial compressor 40.

In addition to the pressure reduction device 42, other elements may be involved in the pressure reduction function, such as the directing device (e.g., flow guide 36) and the fluid sterilization and filtration device 38.

After flowing through the pressure relief device 42, the fluid or air stream 16 flows into the build chamber 20.

The pressure reduction device 42, the fluid sterilization and filtration device 38, the fluid heating device 18 and the flow direction unit 32 may thus produce a pressure reduction of the fluid flow of at least 50 Pa.

The fluid or air stream 16, which has been heated, then flows through the build chamber 20 in a laminar flow, so that it facilitates the desired heating of the build chamber 20 and facilitates the manufacturing of the component with minimal distortion using the 3D printer 12.

In addition, the pressure generated by the fluid flow 16 inside the build chamber 20 should always be higher than the pressure around the build chamber 20 in order to avoid additional particulate loading and contamination from the environment or atmosphere.

After flowing through the build chamber 20, the air flows out of the build chamber 20 and is drawn in again by the radial compressor 40, repeating the above process.

This process is repeated until the printing process is completed or, for example, a malfunction (e.g., too high a concentration of particles) occurs.

The process as described above may also be performed with any other process gas than air as described above, so that air as the fluid is only to be considered as an example.

If the above process is to be performed using a process gas other than air (e.g., an inert gas), the air must be exhausted from the fluid supply system 10 and build chamber 20 of the 3D printer.

The fluid supply system 10 may then be filled with a process gas other than air using the gas connector 46.

Fig. 2 shows a partial cross-sectional view of a configuration chamber inlet area 30 and a flow conductor 36 disposed therein of the fluid supply system 10 according to fig. 1.

The build chamber inlet region 30 includes a diffuser 50 and a flow direction unit 32 attached to the diffuser 50 and embodied in the form of a flow conductor 36.

The diffuser 50 is designed as a hollow cone, the shell surface of which is formed to widen funnel-shaped towards the build chamber (e.g. linearly).

Two or more flow-optimized fastening struts (not shown in fig. 2) may be provided to fasten the flow conductor 36 to the inner wall of the diffuser 50.

The flow conductor 36 according to fig. 2 has a drop-shaped design with a half-dome 52 and a body of revolution 54 which is flush with the largest cross-sectional area of the half-dome and tapers towards the build chamber.

Current carrier 54 tapers from semi-circular top 52 along a longitudinal or rotational axis of current carrier 36 and terminates in a tip.

Current carrier 36 may be formed from the body described above or integrally formed therewith.

The rotating body 36 and diffuser 50 are oriented to be coaxial.

The tip of current carrier 36 faces build chamber 20.

Fig. 3 shows a schematic perspective view of a receiving frame 56 for the 3D printer 12 and for the fluid supply system 10 according to fig. 1.

The receiving frame 56 is composed of three vertical profile supports 58, which three vertical profile supports 58 are oriented to one another according to the corners of an equilateral triangle and are supported in a grid-like manner by additional cross supports. But in principle its plane need not be triangular. Square, rectangular or other basic shapes or plan views are also conceivable.

Build chamber housing 22 is attached to receiving frame 56, the build chamber housing 22 having an outer mesh frame 60, which also has an equilateral triangular shape in cross section.

When installed, the frame 60 has an upper plate and a lower plate that is positioned below the upper plate in the direction of gravity such that the upper plate is spaced apart from the lower plate by a certain height.

The upper and lower plates are also each formed in an equilateral triangle, thus restricting the construction chamber 20 in addition to the outer frame 60.

The upper plate is also connected to the build chamber inlet area 30, while the lower plate supports the build platform and is connected to the casing of the radial compressor 40.

The three corner regions of the upper and lower plates are respectively connected by vertically aligned linear guides 62 (i.e., a total of three linear guides 62), the length of which corresponds to the height between the upper and lower plates.

The outer contour of each linear guide 62 also guides a carriage 64, which carriage 64 can slide vertically relative thereto.

Each of the three carriages 64 has two ball-and-socket joints, to each of which a first end of a rod-shaped arm is hinged.

The second end of each arm is hinged to a print head 26, said print head 26 also having for this purpose two spherical joints for each pair of arms.

Thus, according to fig. 3, the print head 26 has a total of three pairs of ball joints, each facing one carriage 64, and, starting from the three carriages 64, two pairs of arms are respectively connected to the ball joints.

When the print head 26 is assembled, the two arms of each pair of arms are aligned to be parallel to each other.

Thus, the three-dimensional movement of the print head 26 within the build chamber 20 results from its connection to the movement of the three carriages 64 by the arm pairs and the corresponding vertical linear movement of the three carriages 64.

The vertical linear movement of each carriage 64 is achieved by a stepper motor 66, said stepper motor 66 being mounted on the upper plate by means of a bracket and located above said plate. In principle, a servomotor or other drive unit can be used instead of the electric stepping motor 66.

Starting from the stepping motor 66, a belt (e.g., a toothed belt) extends along the entire length of the linear guide 62, said linear guide 62 being of hollow design.

A magnetic coupling element (e.g. another internally guided carriage) is attached to the belt and transfers the linear movement of the belt by magnetic coupling to an externally guided carriage 64 arranged on the outer contour of the linear guide 62. Alternatively, the carriage can also be driven directly, for example by means of a cable traction system or a screw drive. In this way, the internal sledge and the magnetic coupling can be dispensed with.

Fig. 4 shows a more detailed schematic front view of the build chamber 20 of the 3D printer 12 according to fig. 1 and 3.