KR102289037B1 - High temperature bed for glass 3D printer - Google Patents

Abstract

An object of the present invention is to provide a bed to which a glass material can be stably adhered well in a glass material lamination process. In order to achieve the above object, in the present invention, as a laminated bed, which is a space in which molten glass materials are laminated in a 3D printer that melts a glass material through a nozzle for lamination manufacturing, a glass substrate on which a glass material is melted and laminated, the glass substrate A glass melting type 3D printer disposed below and comprising a flat plate heater having the same or wider area than a glass substrate, a flat heater holder surrounding the side and lower surfaces of the flat heater, and an insulating layer disposed between the flat heater and the flat heater holder We provide a laminated bed for

Description

High temperature bed for glass 3D printer

The present invention relates to a high-temperature bed in a glass 3D printer, and more particularly, a high-temperature bed for a glass 3D printer that can be heated to a high temperature suitable for glass lamination and provided with an insulating layer so as not to affect other parts, and a 3D printer using the same is about

Recently, a lot of research has been done on a 3D printer capable of outputting a target object using three-dimensional (3D) data. The market for 3D printers is expected to grow significantly in the future as products with complex structures can be easily printed and produced according to the planned design.

Ceramic 3D printing is a process of making three-dimensional ceramic parts by stacking ceramic materials using digital design data. 3D printing using a 3D printer can be divided into 5 methods in consideration of the characteristics of the material. Material Jetting (MJ), which is discharged by jetting and hardened with ultraviolet rays, etc.; Powder Bed Fusion (PBF), which injects a high-energy beam (laser or electron beam) onto the base material in powder form and selectively binds it, and the adhesive injection method that defects the base material by discharging liquid adhesive onto the base material in powder form (Binder Jetting, BJ).

Double material extrusion (ME), also called fused deposition modeling (FDM), is a method that melts one and the same raw material with high heat, extrudes a small amount at a designated point, and stacks it layer by layer to complete the shape. Mainly, plastic materials such as ABS (acrylonitrile butadiene styrene) and PLA (polylactic acid) are made in filament form and melted while continuously supplied.

Recently, a glass melt deposition type 3D printer has been developed using the material extrusion method (ME). In the case of a 3D printer of the ME method using a plastic material, the ejected plastic material is easily attached to the substrate and growth occurs therefrom. In the case of glass, the melted and ejected glass does not adhere well to the substrate made of glass do. Therefore, in order for the laminate to be successfully printed in the ME method 3D printer, adhesion to the substrate must be preceded.

Such adhesion can be solved by raising the temperature of the substrate, but unlike the case of the conventional plastic material, when a glass material is used, the required substrate temperature is much higher. Accordingly, when the substrate is heated to increase the temperature of the substrate, other components may be affected by the heat of the heated substrate or the heater for heating, which may cause malfunction or damage, and countermeasures are required.

Republic of Korea Registered Utility Model Publication No. 20-0486725

An object of the present invention is to provide a bed to which a glass material can be stably adhered well in a glass material lamination process and a 3D printer using the same.

In order to achieve the above object, in the present invention, as a laminated bed, which is a space in which molten glass materials are laminated in a 3D printer that melts a glass material through a nozzle for lamination manufacturing, a glass substrate on which a glass material is melted and laminated, the glass substrate It provides a laminated bed for a glass melting type 3D printer comprising a flat heater disposed below, a flat heater holder surrounding the side and lower surfaces of the flat heater, and a heat insulating layer disposed between the flat heater and the flat heater holder.

By using the hot bed and the 3D printer provided through the present invention, the glass laminate is stably fixed in the 3D printing process through glass melting, and the heating of the entire 3D printer by the hot bed is prevented, thereby enabling a continuous process.

1 shows an exploded view of a laminated bed according to an embodiment of the present invention.
2 shows a perspective view of a coalesced laminated bed according to an embodiment of the present invention.
3 shows a heat insulating layer and a flat heater according to an embodiment of the present invention.

Hereinafter, the configuration and operation of the embodiment of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, when a part 'includes' a certain component, this means that other components may be further included rather than excluding other components unless otherwise stated.

Through the present invention, as a laminated bed, which is a space in which molten glass materials are laminated in a 3D printer that melts a glass material through a nozzle for lamination manufacturing, a glass substrate on which the glass material is melted and laminated, and a flat plate disposed under the glass substrate It provides a laminated bed for a glass melting type 3D printer comprising a heater, a flat heater holder surrounding the side and lower surfaces of the flat heater, and a heat insulating layer disposed between the flat heater and the flat heater holder.

In a 3D printer that melts a glass material through a nozzle to manufacture it, the adhesive force on the glass substrate to which the glass ejected from the nozzle first adheres is very important to firmly fix the laminate during the continuous lamination process.

In order to increase the adhesive strength, it is necessary to increase the temperature of the glass substrate at which the glass lamination process starts. In the conventional 3D printer using the ME method using plastic as a material, the heating temperature of the bed was only 100° C. or less. In order to increase the adhesive strength of the glass material applied in the present invention, it is necessary to heat the glass substrate to a higher temperature than in the case of plastic, for example, up to 300°C. However, when the glass substrate is heated in this way, the heat from the heated glass substrate and the heat emitted from the heater for heating the glass substrate are transferred to other parts of the 3D printer, causing many problems such as malfunction of electronic devices or dimensional changes due to expansion of metal parts. can cause

In order to prevent this problem, in the present invention, an insulating layer is formed between the flat heater disposed under the glass substrate and the flat heater holder that fixes the flat heater, so that the heat from the flat heater and the glass substrate is transferred to other parts of the 3D printer. make sure it doesn't happen In addition, the flat heater holder disposed under the heat insulating layer can add an effect of blocking heat from the flat heater by applying a heat insulating material such as Teflon.

The flat plate heater heats the glass substrate by raising the temperature of the entire surface while supporting the glass substrate to keep it horizontal. For heating to a high temperature while maintaining the level and for precise temperature control, the flat plate heater can be a metal plate heater (for example, aluminum, stainless steel) or a ceramic plate heater. More preferably, it is a ceramic plate heater that can be made with precision.

It is desirable that the flat heater can control the temperature in the range of 200~700℃, which is a necessary temperature range to cope with various glass materials.

In addition, in the present invention, the heat insulating layer provides a laminated bed for a glass melting type 3D printer comprising a plurality of spherical supports and an empty space.

Various insulating materials such as mineral wool, glass wool, asbestos, and ceramic board may be used for the insulating layer. However, if such an insulating material is located under the flat heater, it may be difficult to secure the horizontality of the flat heater. Due to the nature of materials such as miral wool, glass wool, and asbestos, it is difficult to ensure levelness, and for ceramic boards, it is difficult to achieve a certain level due to the poor level of the board itself or the combination of several board pieces that are not uniform in height. There is a difficult problem.

In order to solve this problem, in the present invention, several spherical supports of the same diameter are placed under the flat heater so that the flat heater is easily maintained. In addition, the thickness of the heat insulating layer has an advantage that can be easily changed by changing the diameter of the spherical support. Because the spherical support and the flat heater are in contact only through a small contact point, heat transfer from the flat heater does not occur easily, and there is an empty space between the spherical support, so that sufficient thermal insulation effect can be obtained.

In addition, in the present invention, the plurality of spherical supports provides a laminated bed for a glass melting type 3D printer that is a ceramic ball.

It is advantageous in terms of thermal insulation effect to use the spherical support itself having low thermal conductivity. On the other hand, heat resistance is also a necessary characteristic because a flat heater heated to a high temperature is located directly on the spherical support. In addition, in order to secure the horizontality of the flat heater positioned on the heat insulating layer, all the spherical supports need to have a uniform diameter, and accordingly, it is preferable that the ball of a uniform diameter be easily made of a material. Therefore, it is preferable that the spherical support is a ceramic ball that does not conduct heat well and is advantageous to make diameters of various and uniform sizes, rather than a ball made of a metal material or plastic that can be melted at a high temperature. In particular, a zirconia ball may be an embodiment that can satisfy these requirements.

In addition, in the present invention, it surrounds the side of the glass substrate and is disposed between the glass substrate and the flat heater holder and is fixed by the flat heater holder and further comprises a glass substrate holder for fixing the glass substrate at the same time, glass melting type 3D A laminated bed for a printer is provided.

The glass substrate needs to be fixed without being shaken during the lamination process, and it is difficult for the glass substrate disposed on the flat plate heater to be directly fixed to the heated flat plate heater. Therefore, the glass substrate can be fixed through the glass substrate holder which is positioned between the flat plate heater holder and the glass substrate and is fixed by the plate heater holder.

When an embodiment according to the present invention is described in more detail with reference to FIGS. 1 to 3 , the glass substrate 110 is a substrate on which molten glass is directly discharged and laminated, and a flat plate for heating the glass substrate 110 immediately below. A heater 120 is disposed. A power supply 121 for supplying power to the heater and a thermocouple 122 for measuring a temperature may be connected to the flat heater 120 .

A spherical support 130 is disposed under the flat plate heater 120 , and a plate heater holder 140 is disposed under it again. The flat plate heater holder 140 has a hollow inside and a hexahedral shape without an upper surface, and the spherical support 130 and the flat plate heater 120 are disposed in the inner space.

The glass substrate 110 disposed on the plate heater 120 may be fixed by the glass substrate holder 150 positioned between the plate heater holder 140 and the glass substrate 110 for more stable fixing. The glass substrate holder 150 is fixed by the plate heater holder 140 .

Figure 2 shows a hot bed in which these parts are incorporated. The spherical support 130 and the plate heater 120 are disposed in the inner space of the plate heater holder 140 , and the glass substrate holder 150 and the glass substrate 110 are disposed thereon.

3 is a heat insulating layer (FIG. 3(a)) formed by the spherical support 130 disposed inside the flat heater holder 140 according to an embodiment of the present invention and the flat heater 120 disposed thereon (FIG. 3(b)) is shown. In an embodiment of the present invention, the spherical support 130 was used as a zirconia ball.

According to the present invention, a glass filament supply device for supplying a glass filament to a nozzle A nozzle that melts the glass filament supplied by the glass filament supply device and discharges it through a nozzle tip, molten glass discharged through the nozzle tip of the nozzle A laminated bed providing a space in which filaments are sequentially laminated to form a target shape, and a control device for controlling the operation of the glass filament supply device and the nozzle, wherein the laminated bed is laminated by melting a glass material A glass melting type 3D printer comprising a glass substrate, a flat plate heater disposed under the glass substrate, a flat heater holder surrounding the side and lower surfaces of the flat heater, and an insulating layer disposed between the flat heater and the flat heater holder do.

By ensuring that the hot bed is placed and at the same time the heat from the hot bed is not transferred to other parts of the 3D printer, the 3D printer can provide a 3D printer that efficiently laminates the glass material on the heated bed while at the same time not being damaged by heat. do.

110: glass substrate 120: flat heater
130: spherical support 140: plate heater holder
150: glass substrate holder

Claims (6)

As a laminate bed, which is a space where molten glass materials are laminated in a 3D printer that melts glass materials through a nozzle and manufactures them,
a glass substrate on which a glass material is melted and laminated;
a flat heater disposed under the glass substrate;
a plate heater holder surrounding the side and lower surfaces of the plate heater; and
Including a heat insulating layer disposed between the flat heater and the flat heater holder,
The heat insulating layer consists of a plurality of spherical ceramic balls having the same diameter and an empty space,
Laminated bed for glass melting type 3D printer. delete delete The method of claim 1,
Surrounding the side surface of the glass substrate and disposed between the glass substrate and the flat heater holder, while being fixed by the flat heater holder further comprising a glass substrate holder for fixing the glass substrate at the same time, glass melting type lamination for 3D printer bed. The method of claim 1,
The flat heater is a ceramic flat heater, a laminated bed for a glass melting type 3D printer. a glass filament supply device for supplying the glass filament to the nozzle;
a nozzle that melts the glass filament supplied by the glass filament supply device and discharges it through a nozzle tip;
a lamination bed providing a space in which molten glass filaments discharged through the nozzle tip of the nozzle are sequentially laminated to form a target shape; and
a control device for controlling the operation of the glass filament supply device and the nozzle;
The laminated bed,
a glass substrate on which a glass material is melted and laminated;
a flat heater disposed under the glass substrate;
a plate heater holder surrounding the side and lower surfaces of the plate heater; and
Including a heat insulating layer disposed between the flat heater and the flat heater holder,
The heat insulating layer consists of a plurality of spherical ceramic balls having the same diameter and an empty space,
Glass melting type 3D printer.

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