KR101859368B1 - Filament connector - Google Patents

Abstract

The present invention relates to a filament connector which is capable of continuously supplying a filament used as material to a three-dimensional printer. The filament connector of the present invention comprises: a base (10); a heater (100) which is provided at an upper side of the base (10) and generates heat by a power source supplied from the outside; a heating block (110) which is provided at an outer side of the heater (100) and is heated by the heat of the heater (100); blocking blocks (130, 132) which are provided at one side of the heating block (110) to form an appearance and block the heat such that heat of the heating block (110) is not transferred to the outside; a cover (300) which is rotatably connected to the blocking blocks (130, 132) and selectively shields upper sides of the heating block (110) and the blocking blocks (130, 132); and liners (200, 202) which are formed to be symmetrical to each other in the heating block (110) and the cover (300), and in which grooves (210, 212) having the filament (20) accommodated therein are formed. Therefore, the filament connector according to the present invention can expect effects that all of the short filament can be used without discarding any one short filament by performing a process of heating and pressing portions where an existing filament and a new filament come in contact with each other, and manufacturing efficiency is improved by consistently supplying the filament.

Description

{FILAMENT CONNECTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a filament connector, and more particularly, to an apparatus for continuously supplying a filament used as a material of a 3D printer without breaking it.

FDM (Fused Deposition) and FFF (Fused Filament Fabrication), which are most commonly used among the various operating methods of 3D printers, are a method of producing output by laminating the ends of filaments used as materials. In the case of using such a 3D printer, filaments can not be supplied continuously, especially when working with a large size molding, and thus conventional filaments must be replaced with new filaments.

In this connection, Korean Patent No. 10-13467074 and Korean Patent No. 10-1430583 disclose relevant technologies.

However, the filament wrapped around the roller can not know the remaining amount of the filament, and therefore, it has to be replaced with a new filament, so that the working time is delayed and the efficiency is lowered.

In addition, even if the remaining amount of the filament is known, if the remaining amount is insufficient for finishing a new operation, there is a problem that the remaining filament can not be used for continuity of operation and must be discarded.

Registration No. 10-1346704 Patent No. 10-1430583

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a method of manufacturing a three-dimensional printer by heating and pressing the end portions of short filaments, And a device for connecting the filament with one long filament to increase the utilization of the filament.

The present invention also provides a device that can be directly attached to a 3D printer or used for portable use.

According to an aspect of the present invention, a filament connector according to the present invention includes a base; A heater provided on the base and generating heat by a power source supplied from the outside; A heating block provided outside the heater and heated by the heat of the heater; A blocking block provided at one side of the heating block to form an appearance and to block the heat of the heating block from being transmitted to the outside; A cover rotatably connected to the blocking block and selectively shielding the upper side of the heating block and the blocking block; And a liner formed symmetrically with respect to the heating block and the cover, respectively, and having a groove in which the filament is received.

Wherein the liner comprises a lower liner contacting the heater or the heating block, and a top liner formed laterally on the bottom surface of the cover; The upper surface of the lower liner is formed so that its height gradually increases toward the center.

The groove is formed in the central portion of the bottom surface of the upper liner in a longitudinal direction of the upper liner and has a semicircular groove-shaped upper groove in contact with the upper surface of the filament. And a bottom groove formed in the center of the upper surface of the lower liner and having a semicircular groove shape which is formed in a lengthwise direction and contacts the bottom surface of the filament.

An overhole is formed in the upper groove to guide the excess filament received in the upper groove through the cover to be discharged to the outside.

The heating block may further include a temperature sensor for measuring a temperature of the heating block, and a temperature adjusting unit for controlling the temperature of the heater may be provided on the base.

According to the present invention, the portions of the filament that are used in the past and the new filament are heated and compressed are connected to each other by using the heat of a heater operated by a power source supplied from the outside. Therefore, since the filament can be used without discarding the filament having a short length, there is an advantage that waste of the filament can be prevented.

Further, since the temperature of the heater can be freely controlled by the temperature controlling means, various types of filaments can be connected.

Also, since the extra filaments generated in the process of overlapping the two filaments are passed through the cover and discharged to the outside, the outer surface of the filament is cleanly formed and can be continuously supplied to the 3D printer.

1 is a perspective view showing a detailed configuration of a filament connector according to the present invention;
2 is a side cross-sectional view showing the configuration of a filament connector according to the present invention.
3 is a front sectional view showing a configuration of a filament connector according to the present invention.
4 is a perspective view showing a state where the cover of the filament connector according to the present invention is lowered.

Hereinafter, preferred embodiments of the filament connector according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a perspective view showing a detailed configuration of a filament connector according to the present invention. In FIGS. 2 and 3, the configuration of the filament connector according to the present invention is shown in a side sectional view and a front sectional view, respectively. 4, the lowered state of the cover 300 is shown in a perspective view.

As shown in these figures, the filament connector according to the present invention includes a base 10, a heater 100 disposed above the base 10 and generating heat by a power source supplied from the outside, A heating block 110 provided on the outside of the heater 100 and heated by the heat of the heater 100 and a heating block 110 disposed on one side of the heating block 110 to form an outer appearance, A cover 300 rotatably connected to the blocking blocks 130 and 132 and selectively shielding the upper portions of the heating blocks 110 and the blocking blocks 130 and 132, And liners 200 and 202 having grooves 210 and 212 formed symmetrically with respect to the heating block 110 and the cover 300 and accommodating the filaments 20 therein.

This will be explained in more detail for each configuration.

The base 10 has a flat plate shape having a predetermined thickness as shown in the figure, and a large number of parts are mounted on the base 10.

A heater 100, a heating block 110, and blocking blocks 130 and 132 are provided on the upper side of the base 10. That is, as shown in the drawing, a heating block 110 is fixed to an upper center of the base 10, and blocking blocks 130 and 132 are fixed to left and right sides of the heating block 110.

The heater 100 is an example of an electric heater that generates heat by using a heat generating function of a current. The heater 100 is accommodated in a heating block 110 to generate heat by a power source supplied from the outside. The heater 100 may be provided in a form capable of providing a temperature at which a filament (polycarbonate, PLA, ABS, etc.), which is a thermoplastic material, can be melted.

The heating block 110 has a predetermined thickness and is formed as a flat plate. The center portion of the heating block 110 is penetrated from the front side to the rear side (as shown in FIG. 3) to cover the outside of the heater 100. The heating block 110 is made of a metal material having a high thermal conductivity and the temperature sensor 120 is further provided on the upper left side of the heating block 110.

The temperature sensor 120 senses the temperature of the heating block 110. The temperature sensor 120 may be an external heating or self-heating type PTC thermistor whose resistance value increases sharply in a narrow range of a specific temperature range. Although not shown in the present invention, the temperature sensor 120 may include an alarm function to inform the user when a dangerous situation occurs in which the heating block 110 is excessively overheated, a temperature control unit 400 to be described later, It is possible to provide an integrated module in which a communication function and a control function are combined.

The first and second blocking blocks 130 and 132 are formed to have the same height as the heating block 110 and have the same shape as the first and second blocking blocks 130 and 132, It is divided. The first blocking block 130 is fixed to the left of the heating block 110 and the second blocking block 130 is fixed to the right of the heating block 110. [ (132) are fixedly installed.

 The blocking blocks 130 and 132 block the heat of the heating block 110 from being transmitted to the outside. Therefore, it is preferable that the blocking blocks 130 and 132 are made of various insulating materials having low thermal conductivity (e.g., synthetic resin).

In addition, protruding portions are formed in the blocking blocks 130 and 132. That is, first protrusions 140 protrude from the back surface (in FIG. 1) of the blocking blocks 130 and 132, respectively. The first protrusion 140 serves as a connection portion for allowing the cover 300, which will be described later, to be rotatably installed.

The cover 300 has a predetermined thickness and is formed to selectively shield the upper side of the heating block 110 and the blocking blocks 130 and 132 and has a lower liner 202 to be described later on a left side surface And a handle 310 is provided on the right side surface (in FIG. 2).

The handle 310 is provided on the upper surface of the cover 300 so as to be easily grasped by the user.

A second projection 150 is provided on the bottom surface of the cover 300 (in FIG. 2). The second protrusion 150 serves as a connection portion for allowing the cover 300 to be rotatably provided, like the first protrusion 140.

More specifically, a second protrusion 150 formed on both left and right ends of the bottom surface (in FIG. 3) of the cover 300 and a first protrusion 140 formed on the upper surfaces of the blocking blocks 130 and 132, respectively, And is hinged through the fixing pin 160.

Liners 200 and 202 are provided on the bottom surface of the cover 300 and on the upper surfaces of the heating block 110 and the blocking blocks 130 and 132, respectively.

The liner 200 and the liner 200 are divided into an upper liner 200 provided in the cover 300 and a lower liner 202 provided in the heating block 110 and the blocking blocks 130 and 132.

First, the lower liner 202 has a shape extending straight in the longitudinal direction of the base 10, and the height of the upper liner is gradually increased toward the center. The lower liner 202 is formed to extend over the upper surface of the heating block 110 and the blocking blocks 130 and 132 in the longitudinal direction of the base 10.

The upper liner 200 has a shape extending straight in the longitudinal direction of the cover 300 and is positioned on a surface opposite to the lower liner 202. It is preferable that the upper liner 200 and the lower liner 202 are made of PTFE (Polytetrafluoroethylene) having good weatherability and non-sticking property and low wear coefficient.

The grooves 210 and 212 are formed in the upper liner 200 and the lower liner 202, respectively. The grooves 210 and 212 are divided into upper grooves 210 as shown in the figure.

The upper groove 210 has a semicircular groove shape which is formed in the center of the bottom surface of the upper liner 200 to be long in the longitudinal direction of the upper liner 200 and in contact with the upper surface of the filament 20. An overhole 220 is formed in the upper groove 210 to guide the excess filament 20 through the cover 300 to be discharged to the outside.

The overhole 220 serves to guide the excess filament 20 to be discharged to the outside. That is, it serves to guide the waste of the unnecessary filaments 20 generated in the process of joining the filaments 20 through the cover 300 to be discharged to the outside.

The lower groove 212 is formed in the center of the upper surface of the lower liner 202 in a longitudinal direction and has a semicircular groove shape in contact with the bottom surface of the filament 20 and is positioned on the opposite surface of the upper groove 210.

That is, the upper groove 210 and the lower groove 212 are provided to allow the filament 20 to be seated, and also prevent the filament 20 from twisting due to thermal deformation or the like in the process of joining the filament 20 The filaments 20 can be held in a state in which the filaments 20 are held.

The upper groove 210 and the lower groove 212 are opposed to each other and the cover 300 is lowered in a direction in which the heating block 110 and the blocking blocks 130 and 132 are installed, And the upper surface of the lower groove 212 come into contact with each other.

On the other hand, a temperature adjusting unit 400 is further provided on the upper left side of the base 10 as shown in FIG. The temperature control means 400 is installed on the left side of the first blocking block 130 (in FIG. 1) and includes a display 410 and an adjusting lever 420.

The display 410 is provided with an LCD or an LED so that the temperature of the heater 100 can be displayed on the screen. The control lever 420 may be a dial or the like capable of setting the temperature of the heater 100 Respectively. That is, since the melting point of the filament 20 varies depending on the material of the temperature regulating means 400, an appropriate temperature is set through the regulating lever 420. These temperature settings are displayed on the display 410 for viewing by the user.

Hereinafter, the operation of the filament connector according to the present invention will be described.

First, since the filament 20 should be placed flat, each filament 20 to be connected is seated in the longitudinal direction of the lower groove 212 of the lower liner 202. Here, it is preferable that each of the filaments 20 is seated so as to overlap the central portion of the lower liner 202. This is because the excess filament 20 generated when the filament 20 is connected is discharged to the outside through the overhole 220 without remaining on one side of the upper liner 200 or the lower liner 202.

When the user lowerens the handle 310 in the direction in which the filament 20 is seated, the cover 300 hinged to the first protrusion 140, the second protrusion 150, and the fixing pin 160, The upper liner 200 and the lower liner 202 come into contact with each other while being lowered in the arrow direction (in Fig. 4). Thus, the empty space between the upper groove 210 and the lower groove 212 is filled with the filament 20, thereby completing preparation for connecting the filament 20.

When the cover 300 completely blocks the heating block 110 and the blocking blocks 130 and 132, the heating temperature corresponding to the melting point of the filament 20 placed through the temperature control unit 400 is set. Generally, the filament 20 of PLA, ABS or the like, which is generally used, has a thickness of about 1.75 mm so that it is connected by heating for a short time in a few seconds. However, in order to cope with a dangerous situation, have.

In addition, although not shown in the present invention, a stand for mounting a roller or the like on which the filament 20 is wound can be separately provided on both sides of the base 10.

As described above, the filament connector according to the present invention is a useful invention for connecting the remaining filaments 20 to the filament 20 and supplying the filament 20 so that the 3D printing operation can be continuously performed. .

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

10. Base 20. Filament
100. Heater 110. Heating block
120. Temperature sensor 130. First blocking block
132. Second blocking block 140. First protrusion
150. Second protrusion 160. Fixing pin
200. Upper liner 202. Lower liner
210. Upper groove 212. Lower groove
220. Overhaul 300. Cover
310. Handle 400. Temperature control means
410. Display 420. Control lever

Claims (5)

A heater 100 disposed on the upper side of the base 10 to generate heat by a power source supplied from the outside and a heater 100 disposed on the outside of the heater 100, A blocking block 130 and 132 installed at one side of the heating block 110 to block the heat of the heating block 110 from being transmitted to the outside, A cover 300 rotatably connected to the heating block 110 and the cover 300 so as to selectively cover the upper side of the heating block 110 and the blocking blocks 130 and 132, A liner (200, 202) having a groove (210, 212) in which a filament (20) is received;
The liner (200, 202)
A lower liner 202 contacting the heater 100 or the heating block 110 and an upper liner 200 formed on the bottom surface of the cover 300 to the left and right;
The grooves 210,
An upper groove 210 formed in the center of the bottom surface of the upper liner 200 in a lengthwise direction of the upper liner 200 and contacting the upper surface of the filament 20, And a bottom groove (212) of a semicircular groove shape formed in the longitudinal direction of the filament (20) and contacting the bottom surface of the filament (20);
In the upper groove 210,
Wherein an overhole (220) is formed to guide the excess filament (20) accommodated in the upper groove (210) through the cover (300) to be discharged to the outside. 2. The filament connector according to claim 1, wherein the upper surface of the lower liner (202) is formed so that its height gradually increases toward the center. delete delete The heating block (110) according to claim 1 or 2, wherein the heating block (110)
A temperature sensor 120 for measuring the temperature of the heating block 110 and a temperature controller 400 for controlling the temperature of the heater 100 are provided on the base 10 .

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