KR20000013569A - Optical fiber extruder - Google Patents

Abstract

PURPOSE: An extruder is provided which prevents an air inlet by installing a funnel type of bottom door, also blowing inert gas into the furnace core. CONSTITUTION: The optical fiber substrate is inserted in a furnace core(250), its lower part is melted by a heater(220). An inert gas is introduced from a gas injection part(230) to prevent the air inlet in the furnace core(250) through an atmosphere keeping member(240), dust generated in the furnace core(250) is flown out. A bottom door(270) fixed in a bottom supplementary part(26) is open when the optical fiber substrate(200) is melt, also prevent the air inlet.

Description

Fiber optic drawing device

The present invention relates to an optical fiber drawing device, and more particularly, to an apparatus for drawing an optical fiber by melting the optical fiber base material.

In general, the maintenance of the atmosphere of an inert gas such as argon (Ar) inside the furnace of the optical fiber drawing device has a great influence on the optical fiber quality. That is, inert gas is introduced into the furnace to block the inflow of external air and guide dust generated inside the furnace to the outside. In this process, the inert gas serves as a carrier.

Argon is a group 8 inert gas that does not react directly with dust or external air generated inside, but forms a flow carrying internal dust as a carrier.

Figure 1a shows a conventional optical fiber extraction apparatus. The optical fiber drawing device according to FIG. 1A includes a furnace core 150 into which an optical fiber base material 100 is inserted, a heater 120 for melting the optical fiber base material 200, a gas injection unit 130 into which an inert gas is injected, and a furnace 150. It is composed of the atmosphere maintaining member 140, the bottom auxiliary portion 160 and the bottom door 170 to flow the injected gas to maintain the atmosphere in the). Reference numeral 110 denotes a furnace.

The optical fiber drawing according to the above-described configuration is performed as follows. First, when the optical fiber base material 100 is inserted into the furnace core 150, the lower end portion of the optical fiber base material 100 is melted by the heater 120. The inert gas supplied to the gas injection unit 130 flows into the inside of the furnace core 140 as an arrow through the atmosphere maintaining member 140 to induce dust generated in the furnace core 140 to the outside. The bottom door 170 coupled to the bottom auxiliary part 160 is opened as the optical fiber base material 100 is melted.

FIG. 1B is a detailed view of the bottom door shown in FIG. 1A. The bottom door according to FIG. 1B includes a hollow flat plate member 171 and a moving flat plate member 172 to which a handle 173 is attached. Reference numeral 174 is an optical fiber to be drawn. Opening the bottom door opens the moving plate member 172 using the handle 173 by the size of the blob generated when the optical fiber base material 100 starts to melt, and when the optical fiber is drawn out, By opening it to a size sufficient to pass through.

However, the planar bottom door described above causes backflow of the inert gas, as indicated by the arrows in FIG. 1A, causing the dust carried by the inert gas to adhere to the hot fiber surface. In addition, when the blob is received from the optical fiber base material, it cannot open and close as much as the blob size, and open more, so that external air cannot be blocked properly.

An object of the present invention is to provide an optical fiber extraction apparatus for maintaining a constant atmosphere of the inert gas in the furnace core and suppressing the inflow of external air by having a funnel-type bottom door with an outer diameter.

Figure 1a shows a conventional optical fiber extraction apparatus.

FIG. 1B illustrates the bottom door of FIG. 1A in more detail.

2 shows an optical fiber drawing device according to the present invention.

3A to 3C show the bottom door of FIG. 2 in more detail.

The present invention for achieving the above technical problem, the furnace core is inserted into the optical fiber base material, a heater mounted on the outside of the furnace core to melt the lower end of the optical fiber base material, a gas injection unit for supplying an inert gas to the furnace core and the furnace In the optical fiber drawing device having a bottom door for passing the optical fiber drawn out from the molten optical fiber base material at the lower end of the core, the bottom door is formed in the shape of a truncated conical shape having a bottom portion that is coupled to the lower end of the furnace core A truncated conical member for passing the melted and drawn optical fiber; And an iris coupled to an upper surface of the truncated member to control the degree of opening according to the diameter of the melted and drawn optical fiber.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 2 shows an optical fiber drawing device according to the present invention. The optical fiber drawing device according to FIG. 2 includes a furnace core 250 into which the optical fiber base material 200 is inserted, a heater 220 for melting the optical fiber base material 200, a gas injection part 230 into which an inert gas is injected, and a furnace 250. Atmospheric holding member 240, the bottom auxiliary portion 260 and the bottom door 270 to flow the injected gas to maintain the atmosphere in the). Reference numeral 210 denotes a furnace.

The optical fiber drawing according to the above-described configuration is performed as follows. First, when the optical fiber base material 200 is inserted into the furnace core 250, the lower end portion of the optical fiber base material 200 is melted by the heater 220. The inert gas supplied to the gas injection unit 230 flows into the inside of the furnace core 240 as an arrow through the atmosphere maintaining member 240 to block the inflow of external air, and is generated from the furnace core 240. Induce dust to outside. The bottom door 270 coupled to the bottom auxiliary part 260 is opened by the size of the blob generated when the optical fiber base material 200 starts to melt, and when the optical fiber is drawn out, the bottom door 270 is opened to the size enough to pass the optical fiber drawn out. Prevent outside air from entering as much as possible.

3A to 3C show the bottom door 270 shown in FIG. 2 in more detail. 3A is a cross-sectional view of a truncated member coupled to the bottom auxiliary portion 260 of FIG. 2. According to FIG. 3A, the truncated member is in the form of a truncated cone having a bottom portion that is coupled to the bottom auxiliary part 300, and has a hollow positioned at the end of the coupling part 302, the truncated passage 304 and the truncated cone 304. And a flat plate member 306. Here, the material of the inner wall of the truncated conical passage 304 is preferably stainless steel. Reference numeral 304-1 denotes a curved portion to prevent backflow of inert gas to the maximum, and 306 denotes a blob.

3B is a cross-sectional view of the iris coupled to the truncated member shown in FIG. 3A. The iris shown in Figure 3b is a funnel 304, the outer diameter is adjusted by the engaging portion 310 coupled to the truncated conical member, the outer diameter adjusting lever 312 and the outer diameter adjusting lever 312 to adjust the opening degree of the iris. Include. Outside diameter control range of the funnel 304 is 5mm ~ 50mm. After the iris is fixed by the coupling part 310, the outer diameter of the funnel 304 is adjusted by the outer diameter adjusting lever 312 according to the size of the blob or the diameter of the optical fiber to thereby suppress the inflow of external air to the maximum.

3C is a plan view of the bottom door. Reference numeral 320 denotes the coupling portion shown in FIG. 3A, and 320 is a passage surface by the portion 304 of FIG. 3A. ψ represents the open range of the iris, and 322 is the optical fiber drawn out.

According to the present invention, in the optical fiber drawing device, the bottom diameter of the funnel type having the outer diameter is adjustable, so that the atmosphere of the inert gas in the furnace core can be kept constant, and the inflow of external air can be suppressed as much as possible. In addition, by providing a funnel-shaped bottom door, it is possible to prevent backflow of the inert gas.

Claims (4)

Furnace core into which an optical fiber base material is inserted, a heater mounted on the outside of the furnace core to melt the lower end of the optical fiber base material, a gas injection unit supplying an inert gas to the furnace core, and the molten optical fiber base material at the bottom of the furnace core In the optical fiber drawing device having a bottom door for passing the optical fiber drawn out from the, the bottom door is A truncated cone-shaped member formed in a truncated conical shape having a bottom portion coupled to the bottom of the furnace core to pass the melted and drawn optical fiber; And And an iris which is coupled to the truncated member and whose opening degree is adjusted according to the diameter of the melted and drawn optical fiber. According to claim 1, wherein the material of the truncated conical member Optical fiber drawing device, characterized in that the stainless steel. The method of claim 1, wherein the side surface of the truncated conical member The optical fiber extracting device, characterized in that the closer to the bottom surface of the truncated conical member so as to prevent the reverse flow of the injected gas is formed into a curved surface. The method of claim 1, wherein the iris is And an external control lever for adjusting the opening degree.