RU202627U1 - A device for cooling the area of the exit of the molten thermoplastic material from the nozzle of a 3D printer and the models obtained from it - Google Patents

Abstract

The device belongs to the field of additive technologies, in particular to devices for cooling the area of the exit of the melt of thermoplastic material from the nozzle of a 3D printer and the models obtained from it using the technology of layer-by-layer fusion. models contain a centrifugal fan, an air duct with an air inlet channel. The air duct is a hollow truncated inverted cone with a blind top wall and an inner wall forming a through hole in its center, the axis of which is perpendicular to the plane of the print area. The outer wall of the air duct on the side of the printable area protrudes relative to the inner wall of the air duct. The inner and outer walls of the air duct form a continuous annular slot for the air flow outlet in the lower plane of the air duct. The air supply channel has a complex cross-sectional geometry. The axis of the air supply channel lies in a plane parallel to the plane of the printable area. The air supply channel is made in one piece with the outer wall of the air duct with the possibility of providing an annular closure of the air flow in the air duct. In a section in a plane parallel to the plane of the printing area, one wall of the air supply channel is located tangentially to the outer wall of the air duct, and the other wall of the air supply channel is directed tangentially to the inner wall of the air duct. The width of the air supply channel does not exceed the distance between the outer and inner walls of the duct. The technical result is to ensure uniform all-round cooling of the area where the melt of thermoplastic material exits from the nozzle of the 3D printer and the models obtained from it.

Description

The device belongs to the field of additive technologies, in particular, to devices for cooling the area where the melt of thermoplastic material exits from the nozzle of a 3D printer and the models obtained from it using the fused deposition technology (FDM).

The cooling device is an important element of a 3D printer using FDM technology, and significantly expands the list of materials used. Typically, such a device is made in the form of an air duct that directs the air flow to the printable area. The air duct is connected to a blower fan or two fans through an air inlet duct.

Often, the air duct is made in the form of a channel with a narrow slot and is located on one side of the nozzle, which leads to uneven cooling of the print area, and, as a consequence, to local overheating of the model, to its deformation due to the creation of uneven pressure, as well as to uneven sintering of layers and, as a consequence, to a decrease in quality and to the fragility of the model.

Another variant of the duct design can be a ring with a hole along its entire length from the bottom, installed around the nozzle of a 3D printer. This version of the duct provides an all-round supply of air flow.

Known cooling device for a 3D printer [1. Pat. 108 327 249 CN, IPC В29С 64/118, etc. Rapid Model cooling device of 3D printer / Chengdu Yuyue Technology Co., LTD. - Applied. 12/21/2017; publ. 07/27/2018.], Providing an air flow to cool the print area from three sides.

Known cooling device for a 3D printer [2. Patent 2018 114384 WO, IPC В29С 64/209, etc. Cooling device for 3D printer / Blythe Daniel J. and others - Appl. 12/22/2016; publ. 06/28/2018.], Providing an all-round supply of air flow into the area of the exit of the thermoplastic melt from the nozzle.

Known cooling device [3. The official WANHAO online store in Russia. - Access mode: https://wanhaorus.ru/p377524507-krugovoj-obduv-dlya.html.], Providing a comprehensive supply of cooling air flow to the print area.

Known device for cooling a model created on a 3D printer [4. Patent 110450416 CN, IPC В29С 64/20, etc. FDM3D (Fused Deposition Modeling Three Dimension) printer model cooling device aimed at PLA (Polylactic Acid) consumables / Lyu Ning, Wang Shaofei, Duan Chongyang. and others - Appl. 09/20/2019; publ. 11/15/2019.], Providing all-round supply of the cooling air flow separately into the area of the exit of the thermoplastic melt and separately into the print area.

The prototype of the claimed utility model is a cooling device [5. Cults. - Access mode: https://cults3d.com/fr/mod%C3%A81e-3d/outil/cooler-for-wanhao-duplicator-i3-stock-fan.], Providing a comprehensive cooling air flow to the print area.

The disadvantages of analogs [1.-4.] And prototype [5.] are as follows:

- the device [1.] does not provide an all-round supply of the cooling air flow; the cooling air flow is directed directly to the area where the nozzle of the 3D printer's print head is located, resulting in unwanted heat away from the nozzle. To compensate for this, the automation of the 3D printer spends additional power to maintain the specified temperature of the nozzle. In addition, such a direction of the air flow can cause overcooling of the thermoplastic just extruded from the nozzle and lead to poor sintering of the thermoplastic layers among themselves;

- the design of devices [1.], [2.] and [3.] does not provide a uniform air flow over the entire area of the holes through which the air flow leaves the duct, which leads to uneven cooling of the model and, as a consequence, to poor sintering of the layers thermoplastic between themselves;

- in the design of the prototype [5.] the air supply channel is connected not only with the outer wall of the air duct, but also with the inner one, which does not provide an annular closure of the air flow inside the air duct. This leads to the appearance of stagnant zones inside the duct and to uneven air flow exiting the duct;

- the presence in the design of the air duct analogue [4.] and prototype [5.] blades of the type of straightening device at the outlet leads to additional losses of air flow power. For these designs, the outgoing air flow is predominantly directed towards the nozzle region, which, as in the device [1.], leads to undesirable heat removal from the nozzle.

The objective of the proposed utility model is to ensure uniform all-round cooling of the region where the melt of thermoplastic material exits from the nozzle of the 3D printer and the models obtained from it, and to minimize the cooling of the nozzle itself.

The claimed device for cooling the area of the exit of the melt of thermoplastic material from the nozzle of the 3D printer and the models obtained from it contains a centrifugal fan, an air duct with an air supply channel. The air duct is a hollow truncated inverted cone with a blind top wall and an inner wall forming a through hole in its center, the axis of which is perpendicular to the plane of the print area. The outer wall of the air duct on the side of the printable area protrudes relative to the inner wall of the air duct. The inner and outer walls of the air duct form a continuous annular slot for the air flow outlet in the lower plane of the air duct. The air supply channel has a complex cross-sectional geometry. The axis of the air supply channel lies in a plane parallel to the plane of the printable area. The air supply channel is made in one piece with the outer wall of the air duct with the possibility of providing an annular closure of the air flow in the air duct. In a section in a plane parallel to the plane of the print area, one wall of the air supply channel is located tangentially to the outer wall of the air duct, and the other wall of the air supply channel is directed tangentially to the inner wall of the air duct. The width of the air supply channel does not exceed the distance between the outer and inner walls of the air duct.

The utility model is illustrated by a drawing (Fig. 1), where:

1 - centrifugal fan;

2 - air duct;

3 - nozzle;

4 - heater;

5 - air flow;

6 - air supply channel;

7 - circular axis of the duct;

8 - annular part of the air duct;

9 - annular slot for air flow outlet;

10 - print area;

11 - a model created on a 3D printer;

12 - the first component of the air flow;

13 - the second component of the air flow;

14 - molten thermoplastic coming from the nozzle;

15 - top layer of thermoplastic;

16 - the lower layer of thermoplastic;

17 - thermal insulation;

18 - heater wall;

19 - inner wall of the duct.

The device operates as follows. Air flow 5 is blown by a centrifugal fan 1 through channel 6 of air supply to the air duct 2. Air flow 5 enters tangentially to the circular axis 7 into the annular part 8 of the air duct 2. From the annular part 8 through the annular slot 9 of the air flow outlet, the air flow 5 leaves the air duct 2 and falls into the print area 10. The outgoing air flow velocity vector 5 has two components. The first component 12 is directed towards the model 11, created on a 3D printer. The second component 13 is parallel to the plane of the print area and is directed tangentially to the circular axis 7 of the duct 2. The total vector of the velocity of the air stream 5 leaving the duct 2:

- provides preferential cooling of the upper layer 15 of the thermoplastic, which is located in the print area 10;

- minimizes the turbulization of the air stream leaving the air duct 2.

Due to this, only a part of the air flow reflected from the surface of the model 11 falls on the nozzle 3 and the molten thermoplastic 14 coming from the nozzle 3. Such an organization of the air flow ensures good sintering of the molten thermoplastic 14 coming from the nozzle 3 with the lower one, that is, earlier laid, with a layer of 16 thermoplastic. This ensures good heat dissipation from the already sintered thermoplastic layers.

The design of the air duct 2 makes it possible to additionally insulate the heater 4. The thermal insulation 17 is located between the wall 18 of the heater 4 and the inner wall 19 of the air duct 2.

The technical result consists in ensuring uniform all-round cooling of the region of the exit of the molten thermoplastic material from the nozzle of the 3D printer and the models obtained from it.

The achievement of the technical result is carried out by the fact that:

- the air supply channel is made in one piece with the outer wall of the air duct with the possibility of providing an annular closure of the air flow in the air duct;

- in a section in a plane parallel to the plane of the printing area, one wall of the air supply channel is located tangentially to the outer wall of the air duct, and the other wall of the air supply channel is directed tangentially to the inner wall of the air duct;

- the width of the air supply channel does not exceed the distance between the outer and inner walls of the air duct.

The advantages of the proposed utility model include:

- energy efficiency in view of the fact that additional electricity consumption is not required to maintain the specified nozzle temperature;

- cost-effectiveness in view of the fact that only one fan is sufficient for the full operation of the device;

- improving the sintering ability of the thermoplastic layers among themselves and, as a consequence, improving the quality and durability of the created model in view of the declared organization of the air flow.

The device can be made using standard equipment and materials of domestic production. Thus, the claimed device meets the criterion of "industrial applicability".

Sources taken into account

1. Pat. 108327249 CN, IPC В29С 64/118, etc. Rapid Model cooling device of 3D printer / Chengdu Yuyue Technology Co., LTD. -Applicated. 12/21/2017; publ. 07/27/2018.

2. Pat. 2018114384 WO, IPC B29C 64/209 et al. Cooling device for 3D printer / Blythe Daniel J. et al. - Appl. 12/22/2016; publ. 28.06.2018.

3. WANHAO official online store in Russia. - Access mode: https://wanhaorus.ru/p377524507-krugovoj-obduv-dlya.html.

4. Pat. 110450416 CN, IPC В29С 64/20, etc. FDM3D (Fused Deposition Modeling Three Dimension) printer model cooling device aimed at PLA (Polylactic Acid) consumables / Lyu Ning, Wang Shaofei, Duan Chongyang. and others - Appl. 09/20/2019; publ. 11/15/2019.

5. Cults. - Access mode: https://cults3d.com/fr/mod%C3%A81e-3d/outil/cooler-for-wanhao-duplicator-i3-stock-fan.

6. Pat. 105904724 CN, IPC В29С 67/00, B33Y 30/00. 3D printer head cooling device / Wang Kaisheng, Han Linsong - App. 04/13/2016; publ. 31.08.2016.

7. Pat. 109795111 CN, IPC B29C 64/20, etc. 3D printer and cooling device thereof / Sun Yuyin, Guo Wantao, Wei Dandan - Appl. 01/23/2019; publ. 24.05.2019.

8. Pat. 204322520 CN, IPC B29C 67/00. Wind direction conversion air duct for filament cooling of 3D printer / Cao Jie, Dai Min - App. 04/09/2014; publ. 05/13/2015.

9. Pat. 204488059 CN, IPC B29C 67/00, B29C 35/16, B33Y 30/00. Printing head for 3D printer with radiating air duct / Wu Huai, Chen Xinyu - Appl. 03/18/2015; publ. 22.07.2015.

10. Pat. 205439283 CN, IPC B29C 67/00, B33Y 30/00. Cooling device of 3D printer / Feng Sen-Appl. 03/31/2016; publ. 08/10/2016.

11. Pat. 206510430 CN, IPC В29С 64/20, B33Y 30/00. 3D printer cooling device / Miao Yifeng - App. 07/28/2016; publ. 22.09.2017.

12. Pat. 206967977 CN, IPC B29C 64/20, B33Y 30/00. 3D printer cooling device / Miao Yifeng - App. 07/28/2016; publ. 22.09.2017.

13. Pat. 207415998 CN, IPC B29C 64/30, B29C 35/16, B33Y 30/00. Cooling device of 3D printer / Li Peixue - Appl. 08/30/2017; publ. 05/29/2018.

14. Pat. 20160297110 US, IPC B29C 35/16, B29C 67/00. Cooling device of print head in 3D printer / Huai WU - Appl. 06/05/2015; publ. 13.10.2016.

15. Pat. 1020160009229 KR, IPC B29C 67/00. Apparatus for cooling filament and filament extruder of 3D printer / Kim, Han Sungkim, Han Sung-App. 07/16/2014; publ. 26.01.2016.

16. Pat. 107009619 CN, IPC B29C 64/20, B29C 35/16, B33Y 30/00. Degree all-directional cooling device in 3D printer / Yang Zhouwang, Wang Kang, Guo Liang-App. 05/10/2017; publ. 04.08.2017.

17. Pat. 106696256 CN, IPC B29C 64/118, B29C 64/209, B33Y 30/00. 3D printing head with air inlet device and cooling method of printing head / Zhao Shunpei, Chen Yuanrong - Appl. 12/05/2016; publ. 24.05.2017.

Claims (1)

A device for cooling the area of the exit of the melt of thermoplastic material from the nozzle of a 3D printer and the models obtained from it, containing a centrifugal fan, an air duct, which is a hollow truncated inverted cone with a blank upper wall and an inner wall forming a through hole in its center, the axis of which is perpendicular plane of the printable area; the outer wall of the air duct from the side of the printable area protrudes relative to the inner wall of the air duct, while the inner and outer walls of the air duct form a continuous annular slot for the outlet of the air flow in the lower plane of the air duct; the air duct contains an air supply channel with a complex cross-sectional geometry; the axis of the air supply channel lies in a plane parallel to the plane of the printable area, characterized in that the air supply channel is made integral with the outer wall of the air duct with the possibility of providing an annular closure of the air flow in the air duct; in a section in a plane parallel to the plane of the print area, one wall of the air supply channel is located tangentially to the outer wall of the air duct, and the other wall of the air supply channel is directed tangentially to the inner wall of the air duct, while the width of the air supply channel does not exceed the distance between the outer and inner the walls of the duct.

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