CN216001450U

CN216001450U - 3D printing device with multiple rows of extrusion holes

Info

Publication number: CN216001450U
Application number: CN202121507500.6U
Authority: CN
Inventors: 黄卫东
Original assignee: Suzhou Meimeng Machinery Co ltd
Current assignee: Suzhou Meimeng Machinery Co ltd
Priority date: 2020-10-12
Filing date: 2021-07-02
Publication date: 2022-03-11
Anticipated expiration: 2031-07-02
Also published as: CN114347466A

Abstract

The application provides a 3D printing device with hole is extruded to multirow. This 3D printing device includes: a feeding device; the material conveying part is connected with the feeding device and is provided with a material inlet and a material outlet; the discharging part is provided with a first row of extrusion holes and a second row of extrusion holes, both of which are communicated with the material conveying part, and the hole pitch of the first row of extrusion holes is different from that of the second row of extrusion holes; and the control part is used for controlling the relative movement of the material conveying part and the material discharging part, so that the first row of extrusion holes or the second row of extrusion holes are communicated with the outlet of the material conveying part in a fluid mode, and a row of filiform materials are extruded simultaneously. The application provides an extrude hole sharing in 3D printing device same material feeding unit and defeated material part, consequently, can simplify 3D printing device's structure and control mode. In addition, because the 3D printing device can be switched among a plurality of rows of extrusion holes with different hole pitches, grid components with different densities can be conveniently printed.

Description

3D printing device with multiple rows of extrusion holes

The present application claims priority from chinese patent application No. 202011087628.1 entitled "3D printing apparatus and control method thereof," filed on 12/10/2020, which is incorporated by reference herein in its entirety.

Technical Field

The utility model relates to a 3D prints the field, concretely relates to 3D printing device with hole is extruded to multirow.

Background

The grid member has the advantages of light weight, cost saving, raw material saving and strong bearing capacity, and therefore, the grid member is widely applied to the industry.

Since the 3D printing apparatus can easily manufacture the mesh member having a complicated structure. Therefore, the 3D printing apparatus has wide application in manufacturing mesh members.

To print out the mesh component, existing 3D printing devices typically employ multiple independent print heads feeding wire simultaneously, with different print heads being responsible for printing different portions of the mesh component. However, the 3D printing apparatus needs to configure the feeding device and the feeding portion corresponding to each of the plurality of printing heads, which results in a complicated structure and control manner of the 3D printing apparatus.

SUMMERY OF THE UTILITY MODEL

The application provides a 3D printing device with a plurality of rows of extrusion holes and a control method thereof, which are used for simplifying the structure and the control mode of the 3D printing device.

In a first aspect, a 3D printing apparatus having a plurality of rows of extrusion orifices is provided, including a feed device for delivering a flowable material; a material conveying part which is connected with the feeding device and is provided with a material inlet and a material outlet; the discharging part is provided with a first row of extrusion holes and a second row of extrusion holes, both of which are communicated with the material conveying part, and the hole pitch of the first row of extrusion holes is different from that of the second row of extrusion holes; and the control part is used for controlling the relative movement of the material conveying part and the material discharging part so that the first row of extrusion holes or the second row of extrusion holes are communicated with the outlet in a fluid mode to extrude a row of filiform materials simultaneously.

In a second aspect, there is provided a method of controlling a 3D printing apparatus, the 3D printing apparatus including: the feeding device is used for conveying flowable materials; a material conveying part which is connected with the feeding device and is provided with a material inlet and a material outlet; the discharging part is provided with a first row of extrusion holes and a second row of extrusion holes, both of which are communicated with the material conveying part, and the hole pitch of the first row of extrusion holes is different from that of the second row of extrusion holes; the control method comprises the following steps: controlling the relative movement of the material conveying part and the material discharging part to ensure that the first row of extrusion holes or the second row of extrusion holes are communicated with the outlet in a fluid manner; a row of extrusion orifices in fluid communication with the outlet is controlled to simultaneously extrude a row of filamentary material.

The utility model provides an extrude hole sharing in 3D printing device with hole is extruded to multirow and same material feeding unit and defeated material part, consequently, can simplify 3D printing device's structure and control mode. In addition, because the 3D printing device can be switched among a plurality of rows of extrusion holes with different hole pitches, grid components with different densities can be conveniently printed.

Drawings

Fig. 1 and fig. 2 are cross-sectional views of a 3D printing apparatus according to an embodiment of the present application.

Fig. 3 is a cross-sectional view of a 3D printing apparatus according to another embodiment of the present application.

FIG. 4 is a side view of an inner and outer sleeve construction provided in accordance with one embodiment of the present application.

Fig. 5 is a cross-sectional view of a 3D printing apparatus according to still another embodiment of the present application.

Fig. 6 is a cross-sectional view of a 3D printing apparatus according to still another embodiment of the present application.

Fig. 7 is a side view of an inner and outer sleeve construction according to another embodiment of the present application.

Fig. 8 is a schematic structural diagram of a mesh component printed by a 3D printing apparatus according to an embodiment of the present application.

Fig. 9 is a schematic structural diagram of a mesh component printed by a 3D printing apparatus according to another embodiment of the present application.

Fig. 10 is a flowchart illustrating a control method of a 3D printing apparatus according to an embodiment of the present application.

Detailed Description

In addition, for some printheads having complex structures, printing the grid members is more challenging. For example, the printhead may employ extrusion orifices capable of supporting disposable face forming (i.e., extrusion orifices whose length may vary with the cross-sectional contour of the part to be printed, as described in WO2018/205149a1, WO2020/087359a1, etc.). The extrusion port of the printing head has a one-dimensional strip characteristic, namely the length of the extrusion port in one dimension is far longer than that in the other dimension, and the extrusion port can change the length along with the change of the cross-sectional profile of a part to be printed in the one dimension, so that a slot type extrusion port with variable length is formed, and the material filling of the whole cross section can be completed on the current forming layer through one unidirectional movement along the cross-sectional profile of the current forming layer. The 3D printing mode with such extrusion outlet features may be generally referred to as "Fused surface deposition 3D printing" (FSD for short). Thus, for FSD, material filling of the entire cross-section is generally achieved, making it difficult to print the mesh members.

To the above problem, the present application provides a simple structure's 3D printing device. The structure of the 3D printing apparatus will be described below with reference to the accompanying drawings.

As shown in fig. 1 and 2, the 3D printing apparatus 10 includes a feeding device 105 and a feeding portion 103.

The feeding device 105 may be used to feed a flowable material (or a material in a molten state). The type of the feeding device 105 can be selected according to actual needs, and may be, for example, a screw type feeding device or a hydraulic type feeding device.

The delivery section 103 may be connected (in fluid communication) with a feed device 105. The delivery section 103 includes an inlet 107 and an outlet 108 for the material. The material delivery portion 103 may be used to deliver the material provided by the material feeding device 105 to the material discharge portion 101.

The outfeed portion 101 of the 3D printing device 10 may include a first row of extrusion orifices 102 (see fig. 1) and a second row of extrusion orifices 106 (see fig. 2). The material transported by the material transporting portion 103 can be extruded outwards through the first row of extruding holes 102 or the second row of extruding holes 106 of the material discharging portion 101, for example, to a printing platform (not shown). The first and

second extrusion orifices

102 and 106 may be in fluid communication with the outlet 108 of the delivery section 103 under different operating conditions.

The outlet 108 for the material may be a groove. The cross-sectional shape of the groove in the embodiment of the present application is not particularly limited, and may be, for example, an elongated rectangular groove, or may be a trapezoid or other shape.

The structure of the discharging portion 101 and the positions of the first and second extruding

holes

102 and 106 on the discharging portion 101 are not particularly limited in the embodiments of the present application. For example, as shown in FIG. 3, the discharging portion 101 may be a shielding plate disposed outside the feeding portion 103. The first and

second extrusion holes

102 and 106 may be provided at different positions of the shielding plate 101, respectively.

For another example, as shown in fig. 4, the feeding portion 103 may be an inner cylinder having a cylindrical shape, and the discharging portion 101 is a sleeve disposed outside the inner cylinder. The first row of extrusion holes 102 and the second row of extrusion holes 106 may be disposed at different positions in the circumferential direction of the sleeve 101, and both the first row of extrusion holes 102 and the second row of extrusion holes 106 may be arranged along the axis of the sleeve 101.

The first row of extrusion orifices 102 has a different orifice spacing than the second row of extrusion orifices 106. For example, the first row of extrusion orifices 102 may have a pitch that is less than the pitch of the second row of extrusion orifices 106. In other words, the extrusion orifices in the first row of extrusion orifices 102 are more densely arranged and the extrusion orifices in the second row of extrusion orifices 106 are more sparsely arranged. The different densities of the first row of extrusion orifices 102 and the second row of extrusion orifices 106 allow them to be used to print different types of grid members.

The 3D printing apparatus 10 further includes a control section 104. The control section 104 may be adapted to control the first or

second extrusion orifices

102, 106 to be in fluid communication with the outlet 108 of the delivery section 103 to simultaneously extrude a strand of material. For example, when it is desired to print a grid structure with a higher density as shown in fig. 8(b), a first row of extrusion orifices 102 with smaller orifice spacing may be controlled to be in fluid communication with the outlet 108, and layer-by-layer 3D printing may be performed using the first row of extrusion orifices 102; when it is desired to print a grid member having a lower density as shown in fig. 8(a), a second row of extrusion orifices 106 having a larger orifice spacing may be controlled to be in fluid communication with the outlet 108, and layer-by-layer 3D printing may be performed using the second row of extrusion orifices 106.

The control means of the control section 104 may be various. For example, when the discharging portion 101 is configured as a shutter as shown in fig. 3, the control portion 104 may control the shutter-like discharging portion 101 and the transporting portion 103 to slide relatively to select a row of extruding holes, which is in fluid communication with the outlet 108 of the transporting portion 103, from among the first row of extruding holes 102 and the second row of extruding holes 106. For another example, when the discharge portion 101 is configured as a sleeve as shown in fig. 4, the control portion 104 may control the sleeve-shaped discharge portion 101 and the cylindrical delivery portion 103 to rotate relatively, so as to select a row of extrusion holes from the first row of extrusion holes 102 and the second row of extrusion holes 106, which is in fluid communication with the outlet 108 of the delivery portion.

The extrusion holes in the 3D printing device 10 share the same feeding device and feeding portion, and therefore, the structure and control manner of the 3D printing device 10 can be simplified. In addition, since the 3D printing apparatus 10 can switch between a plurality of rows of extrusion orifices having different orifice pitches, mesh members having different densities can be conveniently printed out.

The control portion 104 may also be adapted to control the relative movement of the discharging portion 101 and the feeding portion 103 in a first direction (the first direction may be the arrangement direction of the first row of the extruding holes 102 or the length direction of the outlet 108 of the feeding portion 103, i.e., the x direction in fig. 1 and 2) when the first row of the extruding holes 102 is in fluid communication with the outlet 108 of the feeding portion 103. Relative movement between the discharging portion 101 and the feeding portion 103 in the first direction causes some of the extrusion holes in the first row 101, which are originally connected to the feeding portion outlet 108, to move to the outside of the area where the feeding portion outlet 108 is located, thereby being in a blocked state. Therefore, the above-described control of the control portion 104 may vary the number of the extrusion holes of the first row of extrusion holes 102 which are in fluid communication with the delivery portion outlet 108. In this way, the 3D printing apparatus 10 may adjust the number of extrusion holes according to the specific structure of the mesh component to be printed, thereby improving the flexibility of the 3D printing apparatus 10.

In 3D printing processes, it is often necessary to pause the printing process. For example, when the contour edge of the cross section is printed, the printing process needs to be suspended, the 3D printing device is moved to a new printing start position, and the subsequent printing process is resumed. Because the materials (such as high polymer materials) adopted by the 3D printing technology generally have viscoelasticity, when the feeding device stops conveying the materials, the flow of the materials cannot be stopped suddenly, and at the moment, the materials can be continuously accumulated outside the contour edge of the section to be printed, so that the contour shape of the printing section is damaged, and the geometric accuracy of a printed part is reduced.

In order to solve the above problems, in some embodiments, when the first row of extrusion holes 102 is in fluid communication with the outlet 108 of the delivery section 103, the control section 104 may control the relative movement of the delivery section 103 and the discharge section 101 so that all the extrusion holes in the first row of extrusion holes 101 and the delivery section outlet 108 are simultaneously misaligned.

For example, in the embodiment shown in fig. 3, the control part 104 may control the shutter-like discharging part 101 to slide from the position shown in fig. 3(a) to the position shown in fig. 3(b) so that all the extruding holes of the first row of extruding holes 102 and the discharging part outlet 108 are simultaneously misaligned.

For another example, in the embodiment shown in fig. 4, the control portion 104 may control the inner cylindrical delivery section 103 and the sleeve-shaped discharge section 101 to rotate from the position shown in fig. 4(a) to the position shown in fig. 4(b), so that all the extrusion holes of the first row of extrusion holes 102 and the outlet 108 of the delivery section 103 are simultaneously misaligned.

In some embodiments, as shown in fig. 5, a third discharge orifice 109 may be provided in the outlet 108 of the delivery section 103. The material in the delivery section 103 can be extruded to the outside of the delivery section 103 through the third extrusion outlet 109. In order to enable the third row of extrusion orifices 109 to better mate with both the first row of extrusion orifices 102 and the second row of extrusion orifices 106, the orifice pitch of the third row of extrusion orifices 109 may be designed to be less than or equal to the smaller of the orifice pitches of the first row of extrusion orifices 102 and the second row of extrusion orifices 106.

When the material is extruded through the extrusion hole, the resistance may be very large, and a very high extrusion pressure needs to be provided to extrude the material from the extrusion hole at a required rate, which results in a large structural size and energy consumption of the whole system, and reduces the economy of the 3D printing device. Since the resistance of the material to extrusion through the extrusion orifice is proportional to the depth of the extrusion orifice, the resistance to extrusion of the material can be reduced by reducing the depth of the extrusion orifice.

For example, as shown in fig. 6, in some embodiments, a recess 110 may be cut above the third row of extrusion orifices 109, such that the channel depth is reduced by a channel depth dimension from the original wall thickness dimension of the wicking portion 103, and the depth of the extrusion orifices is reduced by the distance from the bottom of the recess 110 to the outer surface of the wicking portion 103. The shape and depth of the groove 110 are not particularly limited, and may be selected according to specific situations. For example, the groove 110 may be designed as an arc-shaped groove.

As another example, as shown in FIG. 7, in other embodiments, the thickness of the sleeve-like outfeed section 101 at a location corresponding to the extrusion orifice may be reduced to reduce the depth of the extrusion orifice. Specifically, the wall of the barrel where the extrusion hole is located may be thinned in a certain arc shape.

The shape of the sleeve-like discharge member 101 does not necessarily have to be cylindrical, but may be any other shape. For example, referring to fig. 7, the upper portion of the sleeve-like take-off member 101 may be designed to be thick and large to facilitate installation of the heater 111 therein.

The grid structure has different shapes according to different appearance or structure requirements. This can be achieved by changing the motion pattern of the 3D printing device. Optionally, when printing different layers, the 3D printing apparatus may deflect by a certain angle, and the setting of the deflection angle is not particularly limited, and may be any deflection angle. For example, the printing of the mesh structure shown in fig. 8 is achieved by deflecting the movement direction of the 3D printing device by 90 ° at the time of interlayer printing. For another example, the printing of the mesh structure shown in fig. 9(a) is performed by deflecting the moving direction of the 3D printing apparatus by 45 ° at the time of interlayer printing.

Furthermore, in some embodiments, different relative motion modes may be employed between the 3D printing device and the printing platform, for example, when printing the structure shown in fig. 9(a), the relative motion mode between the 3D printing device and the printing platform is a linear motion mode; when the structure shown in fig. 9(b) is printed, the relative motion mode between the 3D printing device and the printing platform is a linear motion mode combined with a curvilinear motion mode; when the structure shown in fig. 9(c) is printed, the relative motion pattern between the 3D printing apparatus and the printing platform is a pure curvilinear motion pattern. The embodiment of the application has no specific limitation on the relative motion mode between the 3D printing device and the printing platform, and different motion modes can be freely combined, so that grid members with various structures are formed.

The shape of the extrusion hole is not specifically limited in the embodiment of the application, and the extrusion hole can be a square hole or a round hole. The diameter of the extrusion holes is different, and the thickness of the printed layer formed by a row of materials is also different. Thus, the monolayer print thickness can be varied by varying the aperture of the extrusion orifice. The embodiment of the application defines the specific size difference of aperture, can set up according to actual need. For example, for precision printing, an aperture of 0.1mm or less may be employed to form an ultra-thin print layer with a single layer print thickness of less than 0.1 mm; as another example, for high efficiency printing, an aperture diameter of 1mm or greater may be employed to form an ultra-thick print layer with a single layer print thickness of 1mm or greater.

The 3D printing device that this application embodiment provided can indicate 3D and beat printer head, also can indicate whole 3D printing system. The control portion of the 3D printing apparatus may be implemented by software, hardware, or a combination of software and hardware, which is not limited in this embodiment of the application.

The device embodiments of the present application are described in detail above in conjunction with fig. 1-9. Method embodiments of the present application are described below in conjunction with fig. 10. It is to be understood that the description of the method embodiments corresponds to the description of the apparatus embodiments, and therefore reference may be made to the preceding apparatus embodiments for parts which are not described in detail.

Fig. 10 is a schematic flowchart of a control method of a 3D printing apparatus according to an embodiment of the present application. This 3D printing device includes: the feeding device is used for conveying flowable materials; a material conveying part which is connected with the feeding device and is provided with a material inlet and a material outlet; and the discharging part is provided with a first row of extrusion holes and a second row of extrusion holes which are both communicated with the material conveying part, and the hole intervals of the first row of extrusion holes are different from those of the second row of extrusion holes. The structure of the 3D printing apparatus can be seen from the foregoing description. The control method of fig. 10 includes steps S1010 to S1020.

In step S1010, the relative movement of the feeding portion and the discharging portion is controlled such that the first or second discharge hole is in fluid communication with the outlet of the feeding portion. In step S1020, a row of extrusion orifices in fluid communication with the delivery section outlet is controlled to simultaneously extrude a row of filamentary material.

Optionally, in some embodiments, when the first row of extrusion holes is in communication with the outlet, step S1010 may include: and controlling the relative movement of the material conveying part and the material discharging part along a first direction to change the number of the extrusion holes in the first row of extrusion holes, which are in fluid communication with the outlet, wherein the first direction is the arrangement direction of the first row of extrusion holes.

Optionally, in some embodiments, when the first row of extrusion orifices is in communication with the outfeed portion outlet, the method of fig. 10 further comprises: and controlling the relative motion of the material conveying part and the material discharging part to enable the first row of extrusion holes to move to the outside of the area where the outlet is located so as to simultaneously shut off the first row of extrusion holes.

Optionally, in some embodiments, the delivery part is an inner cylinder in a cylindrical shape; the discharge part is a sleeve of the inner cylinder, the first row of extrusion holes and the second row of extrusion holes are arranged along the axial direction of the inner cylinder, and the method shown in fig. 10 further comprises the following steps: the inner cylinder and the sleeve are controlled to rotate relatively along the axis so as to control the first row of extrusion holes or the second row of extrusion holes to be communicated with the outlet of the discharging part in a fluid mode.

Optionally, in some embodiments, the discharging portion is a shielding plate disposed outside the feeding portion and slidably connected to the feeding portion, and the method shown in fig. 10 further includes: the control baffle plate and the material conveying part slide relatively to control the fluid communication between the first row of extrusion holes or the second row of extrusion holes and the outlet of the material discharging part.

Optionally, in some embodiments, the 3D printing apparatus further includes a third row of extrusion holes located in the outfeed portion outlet, and the pitch of the third row of extrusion holes is smaller than or equal to the pitch of any one of the first row of extrusion holes and the second row of extrusion holes, and the method shown in fig. 10 further includes: controlling the relative motion of the material conveying part and the material discharging part to ensure that the first row of extrusion holes or the second row of extrusion holes are communicated with the third row of extrusion holes in a fluid mode.

Optionally, in some embodiments, the feeding portion has a groove therein, and the third extrusion hole is located below the groove.

Claims

1. A3D printing device with multiple rows of extrusion orifices, comprising:

the feeding device is used for conveying flowable materials;

the material conveying part is connected with the feeding device and is provided with an inlet and an outlet of the material;

the discharging part is provided with a first row of extrusion holes and a second row of extrusion holes, both of which are communicated with the material conveying part, and the hole pitch of the first row of extrusion holes is different from that of the second row of extrusion holes;

and the control part is used for controlling the relative movement of the material conveying part and the material discharging part, so that the first row of extrusion holes or the second row of extrusion holes are communicated with the outlet in a fluid manner, and a row of filiform materials are extruded simultaneously.

2. The 3D printing device according to claim 1, characterized in that:

the control part is also used for controlling the material conveying part and the material discharging part to relatively move along a first direction when the first row of extrusion holes are communicated with the outlet so as to change the number of the extrusion holes which are in fluid communication with the outlet in the first row of extrusion holes, wherein the first direction is the arrangement direction of the first row of extrusion holes.

3. The 3D printing device according to claim 1, characterized in that:

the control part is also used for controlling the relative motion of the material conveying part and the material discharging part when the first row of extrusion holes are communicated with the outlet, so that the first row of extrusion holes move to the outside of the area where the outlet is located, and the first row of extrusion holes are simultaneously closed.

4. The 3D printing device according to claim 1, characterized in that:

the material conveying part is an inner cylinder in a cylindrical shape;

the discharge part is a sleeve of the inner cylinder, and the first row of extrusion holes and the second row of extrusion holes are arranged along the axial direction of the inner cylinder;

the control part is also used for controlling the inner cylinder and the sleeve to relatively rotate along the axis so as to control the first row of extrusion holes or the second row of extrusion holes to be communicated with the outlet in a fluid mode.

5. The 3D printing device according to claim 1, characterized in that:

the discharging part is a shielding plate which is arranged on the outer side of the material conveying part and is in sliding connection with the material conveying part;

the control part is also used for controlling the shielding plate and the material conveying part to slide relatively so as to control the first row of extrusion holes or the second row of extrusion holes to be communicated with the outlet in a fluid mode.

6. The 3D printing device according to any of claims 1-5, further comprising:

a third row of extrusion orifices in the outlet, the third row of extrusion orifices having a hole pitch less than or equal to the hole pitch of any one of the first row of extrusion orifices and the second row of extrusion orifices;

the control part is used for controlling the relative motion of the material conveying part and the material discharging part, so that the first row of extrusion holes or the second row of extrusion holes are communicated with the third row of extrusion holes in a fluid mode.

7. The 3D printing device as claimed in claim 6, wherein the feeding portion has a groove therein, and the third row of extrusion holes are located below the groove.