JPH0578139A - Device for drawing preform base material for optical fiber - Google Patents

Abstract

PURPOSE:To provide a drawing device capable of drawing a preform base material for optical fiber in high accuracy without curving the base material. CONSTITUTION:A lifting and lowering device 20 which holds an upper end part of a preform base material 2 for optical fiber passing through passage of the heating furnace 10 and can lift and lower the base material 2 is arranged above the heating furnace having vertical passage. Plural pairs of taking-off units 30 and 40 consisting of a pair of driving rollers 32 and 42 for taking off the base material 2 downward vertically while pressing on the side of the base material 2 and rotating and outside diameter measuring devices 31 and 41 for measuring the outside of the preform base material 2 closer to the heating furnace side than these driving rollers 32 and 42 are arranged along the course of the preform, base material 2. These driving rollers 32 and 42 can be separated from the preform base material 2 every each take-off units 30 and 40.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for drawing a preform preform for optical fibers to a predetermined outer diameter.

[0002]

2. Description of the Related Art An optical fiber is manufactured by drawing a fiber while heating a preform base material. The large-diameter preform base material is drawn while being heated by an oxyhydrogen burner or a heating furnace to have a diameter suitable for wire drawing.

A stretching device as shown in FIG. 7 is used for stretching the preform base material. In this device, an elevating device 20 is arranged above a heating furnace 10 whose upper surface and a lower surface are open, and a take-up device 50 is arranged below. The lifting device 20 includes a ball screw shaft 24 connected to a drive source 23.
The rotation of the chuck moves the chuck 22 up and down. The take-up device 50 is a ball screw shaft 5 connected to a drive source 51.
The structure is such that the chuck 53 moves up and down by the rotation of 2.
The base material 2 is vertically supported by being held by the chuck 22 at the upper end and the chuck 53 at the lower end, and penetrates the heating furnace 10.

The heating furnace 10 is energized to soften the base material 2,
When the lifting device 20 is driven to lower the chuck 22 and the chuck 53 of the take-up device 50 is lowered at a speed higher than the lowering speed of the chuck 22, the base material 2 is sequentially stretched from the take-up device 50 side.

However, this apparatus is not suitable for stretching a long base material 2 because the lower end of the base material 2 is gripped and pulled. This is because the stretched length of the base material 2 is limited by the movable distance of the chuck 53. In order to stretch the long base material 2, it is necessary to set the movable distance of the take-up device 50 to be equal to or more than the stretched length, and the whole device becomes large-scale.

Therefore, as shown in FIG. 8, a drawing device using a pair of drive rollers 61 is used as the take-up device 50. By rotating the drive roller 61 pressed against the base material 2 as indicated by an arrow, it is possible to perform an operation that combines the holding of the base material 2 and the take-up drive for stretching. Since the drive roller 61 itself does not move, it is possible to stretch the long base material 2 without enlarging the entire apparatus.

[0007]

However, this drawing apparatus has the following problems. When the optical fiber preform 2 has a large diameter, a ball-shaped bulge 2a is formed at the portion where the stretching is started.
Is likely to occur. Base material 2 is taken in order and bulges 2
When a is sandwiched by the drive rollers 61, the base material 2 may be bent in the stretching direction as shown in FIG. 9, and the base material 2 after stretching may be curved. When the base material 2 having a diameter of 90 mm and a length of 1000 mm was drawn to have a diameter of 35 mm and a length of 6600 mm by using the drawing device of FIG. There was a case where the maximum deviation d reached 15 mm.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a stretching device capable of highly accurately stretching a preform preform for an optical fiber without bending.

[0009]

An optical fiber preform preform stretching apparatus of the present invention, which has been made to achieve the above object, will be described with reference to FIG. 1 corresponding to an embodiment.

As shown in FIG. 1, the optical fiber preform base material drawing apparatus of the present invention has an optical fiber preform vertically penetrating the passage of the heating furnace 10 above the heating furnace 10 having a vertical passage. An elevating device 20 capable of lifting and lowering by grasping an upper end portion of the base material 2 is disposed, and a pair of drive rollers 32 and 42 which are pressed to rotate on a side surface of the preform base material 2 and rotate vertically below the heating furnace 10 while being pressed against the side surface of the preform base material 2. And the drive roller 32
A take-up device 3 including outer diameter measuring devices 31 and 41 for measuring the outer diameter of the preform base material 2 closer to the heating furnace than 42
A plurality of sets of 0.40 are arranged along the path of the preform base material 2. The drive rollers 32 and 42 can be separated from the preform base material 2 for each of the take-up devices 30 and 40.

[0011]

As shown in FIGS. 1 and 2, when two pairs of driving rollers 32 and 42 are pressed against the base material 2 and rotationally driven as shown by the arrows, the preform base material 2 softened in the heating furnace 10
Is stretched and drawn downward. In parallel with this operation, when the elevating device 20 is driven to gently lower the base material 2,
The base material 2 is sequentially stretched from the lower side.

When a bulge 2a is generated at the stretching start portion of the base material 2, the bulge 2a approaches the take-up device 30 as the stretching progresses. Then, the outer diameter measuring device 31 detects the approach of the bulge 2a, and the drive roller 32 is separated from the base material 2 as shown in FIG. At this time, the base material 2 is taken only by the driving force of the driving roller 42, and the bulge 2a moves downward between the driving rollers 32 without contacting the driving rollers 32.
After passing through the bulge 2a, the drive roller 32 is pressed against the base material 2 again (see FIG. 4). When the bulge 2a further descends and approaches the take-up device 40, the approach is taken to the outer diameter measuring device 4
1 and the drive roller 42 as shown in FIG.
Separate from the base material 2. The base material 2 is taken only by the driving force of the driving roller 32, and the bulge 2a moves downward without contacting the driving roller 42. After passing through the bulge 2a,
The drive roller 42 is pressed against the base material 2 and rotated as shown in FIG.
The stretching is continued together with the driving roller 32.

[0013]

EXAMPLES Examples of the present invention will be described below. FIG. 1 is a front view of an optical fiber preform base material drawing apparatus to which the present invention is applied. In this apparatus, a heating furnace 10 is attached to a frame 12 provided on a base 11, and an elevating device 2 is installed above the heating furnace 10.
0, the first take-up device 30 and the second take-up device 40 are arranged below.

The heating furnace 10 is an electric furnace having an open upper surface and a lower surface, and has a passage penetrating in the vertical direction.

The lifting device 20 is a device in which a chuck 22 moves up and down on the front surface of a substrate 21 provided vertically on the upper surface of the frame 12. The chuck 22 is moved up and down by the rotation of the ball screw shaft 24 connected to the drive source 23. The preform base material 2 is gripped by the chuck 22 and vertically penetrates the heating furnace 10. The axis of the base material 2 coincides with the axis of the passage of the heating furnace 10.

The first take-up device 30 comprises a pair of drive rollers 32 and an outer diameter measuring device 31 for measuring the outer diameter of the base material 2. The drive rollers 32 are a pair of rollers that rotate while sandwiching the base material 2 protruding below the heating furnace 10.
Each roller is connected to a drive source 37 via a chain belt 34. The drive roller 32 is attached to an air cylinder 33 that reciprocates in the horizontal direction. The outer diameter measuring device 31 is a laser outer diameter measuring device. Heating furnace 1 rather than drive roller 32
The outer diameter of the base material 2 on the 0 side is measured, and when the outer diameter of the base material 2 exceeds a specific value, the air cylinder 33 is operated to separate the drive roller 32 from the base material 2. ing.

The second take-up device 40 is composed of an outer diameter measuring device (laser outer diameter measuring device) 41, a drive roller 42 and an air cylinder 43, and has the same structure as the first take-up device 30 described above. The second take-up device 40 is
It is arranged below the first take-up device 30.

This device is used as follows. The drive source 23 is operated to move the chuck 22 of the lifting device 20 upward. The air cylinders 33 and 43 are operated to keep the drive rollers 32 and the drive rollers 42 apart from each other. The end portion of the base material 2 is grasped by the chuck 22, suspended vertically, and attached to the lifting device 20. The dummy rod 3 is connected to one end of the base material 2 and the dummy rod 4 is connected to the other end thereof, and the chuck 22 holds the dummy rod 3. The chuck 22 is lowered to guide the base material 2 into the heating furnace 10, and the heating furnace 1
The tip of the dummy rod 4 protruding below 0 is the drive roller 32.
When reaching the lower side, the lifting device 20 is stopped, the air cylinder 33 is operated, and the dummy rod 4 is held by the drive roller 32.

When the heating furnace 10 is energized and the base material 2 begins to soften, the elevating device 20 is driven to gently lower the entire base material 2 and the drive roller 32 is rotated to move the base material vertically downward. Take up and start stretching. Drive roller 32
The take-up speed is set based on a predetermined draw ratio. When the tip of the dummy rod 4 reaches below the drive roller 42, the air cylinder 43 is operated to press and rotate the drive roller 42 against the dummy rod 4 as shown in FIG. Take 2 vertically down.

When the base material 2 has a large diameter, dumpling-like swelling 2a may occur at the portion where the stretching is started. The dummy rod 4 is pulled downward, and the bulge 2a becomes the drive roller 3
When approaching 2, the outer diameter measuring device 31 detects a change in the outer diameter of the base material 2, and the air cylinder 33 operates to separate the drive roller 32 from the base material 2. The base material 2 is taken only by the driving force of the drive roller 42, and the bulge 2a moves downward without contacting the drive roller 32 (see FIG. 3). After the bulge 2a passes between the drive rollers 32, the drive roller 3
2 is pressed against the base material 2 again by the action of the air cylinder 33, and as shown in FIG.

When the bulge 2a approaches the take-up device 40 as the drawing further progresses, the outer diameter measuring device 41 detects the change in the outer diameter of the base material 2 and operates the air cylinder 43 to drive the driving roller as shown in FIG. 32 is separated from the base material 2. Base material 2
Is taken up only by the driving force of the driving roller 32, and the bulge 2
a moves downward without contacting the drive roller 42. After the bulge 2a passes between the drive rollers 42, the drive roller 42 is pressed against the base material 2 again as shown in FIG.

Even when the bulge 2a is generated on the base material 2 as described above, the drive roller 32 and the drive roller 42 are retracted in accordance with the movement of the bulge 2a, and the bulge 2a contacts the drive roller 32 and the drive roller 42. There is nothing to do. Therefore, the preform 2 for the optical fiber is always taken out in the vertical direction at a constant speed, and the preform preform 2 for optical fiber having no curvature is obtained. A base material 2 having a diameter of 90 mm and a length of 1000 mm was drawn to a diameter of 35 mm and a length of 6600 mm by using this drawing device.
The stretched base material 2 had a curvature of only 0.2 mm.

[0023]

As described above in detail, in the optical fiber preform base material drawing apparatus of the present invention, the drive roller is pressed against only the straight portion of the preform base material and rotated to pull it out. The preform preform for optical fibers can also be stretched without bending.

[Brief description of drawings]

FIG. 1 is a front view of an optical fiber preform base material drawing apparatus to which the present invention is applied.

FIG. 2 is a schematic process diagram for explaining the operation of the optical fiber preform base material drawing apparatus to which the present invention is applied.

FIG. 3 is a schematic process diagram illustrating the operation of an optical fiber preform base material drawing apparatus to which the present invention is applied.

FIG. 4 is a schematic process diagram for explaining the operation of the optical fiber preform base material drawing apparatus to which the present invention is applied.

FIG. 5 is a schematic process diagram for explaining the operation of the optical fiber preform base material stretching device to which the present invention is applied.

FIG. 6 is a schematic process diagram for explaining the operation of the optical fiber preform base material drawing device to which the present invention is applied.

FIG. 7 is a front view of a conventional optical fiber preform base material drawing device.

FIG. 8 is a schematic view illustrating the operation of a conventional optical fiber preform base material drawing device.

FIG. 9 is a schematic view for explaining the operation of a conventional optical fiber preform base material drawing device.

FIG. 10 is a side view of a base material drawn by a conventional optical fiber preform base material drawing apparatus.

[Explanation of symbols]

2 is a preform base material for an optical fiber, 2a is a bulge, 2
b is a curved part, 3.4 is a dummy rod, 10 is a heating furnace, 11 is a base, 12 is a frame, 20 is a lifting device, 21 is a substrate,
22 and 53 are chucks, 23 and 37 and 51 are drive sources, 2
4/52 is a ball screw shaft, 30/40/50 is a take-up device, 31/41 is an outer diameter measuring device, 32/42/61 is a drive roller, 33/43 is an air cylinder, 34 is a chain belt, and 50 is a take-up device. It is a device.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Hideo Hirasawa Inventor Hideo Hirasawa 2-13-1, Isobe, Annaka-shi, Gunma Shin-Etsu Chemical Co., Ltd. Precision Materials Research Laboratory

Claims (1)

[Claims] 1. A heating furnace is provided above a heating furnace having a vertical passage, and an elevating device capable of holding and lifting an upper end portion of an optical fiber preform preform vertically penetrating the passage of the heating furnace is provided. , A pair of drive rollers that rotate by pressure contact with the side surface of the preform base material and pull vertically downward, and an outer diameter measuring device that measures the outer diameter of the preform base material on the heating furnace side of the drive rollers. A plurality of sets of take-up devices are arranged along the path of the preform preform, and the drive roller can be separated from the preform preform for each take-up device. ..