JP3871238B2 - Automatic processing method and automatic processing apparatus for optical fiber preform - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an automatic processing apparatus for preforms for optical fibers (hereinafter simply referred to as “preforms”), and more particularly to an automatic processing method and an automatic processing apparatus for preforms that are useful and safe when a fire is extinguished.
[0002]
[Prior art]
Conventionally, a large-sized optical fiber preform made of quartz glass produced by a VAD method or an OVD method is drawn to a predetermined diameter using a drawing furnace or by a glass lathe, and further drawn to obtain an optical fiber. In this stretching process, an oxygen-hydrogen flame is employed as the heating means in the glass lathe process in which the shape of the preform and the finish of the surface are finally finished.
In the finishing process using this glass lathe, conventionally, the state of the flame coming out of the burner and the brightness of the surface of the preform to be heated are visually observed, and the supply amount of hydrogen and oxygen of the combustible gas is controlled by a valve. Stretching and flame polishing.
[0003]
However, skill is required to adjust the gas flow rate by visually observing the state of the flame coming out of the preform processing burner (hereinafter simply referred to as the processing burner) and the brightness of the heated preform surface. In addition, it is a dangerous operation for handling a member heated to a high temperature, and in addition, the working environment was high and poor due to the radiant heat from the flame and the preform.
In order to solve such a problem, a series of operations in the glass lathe process is almost shifting to automation using a computer. As automation progresses, the number of workers required per glass lathe is about 0.2 to 0.3.
[0004]
As a result of such automation, work efficiency and work environment have been greatly improved and productivity has been improved, but on the other hand, there has been a problem with safety.
Normally, the ignition to the processing burner is performed with a fire. However, in the above-described automatic device, the fire is always burned with a flammable gas such as hydrogen gas. When combustible gas is supplied to the burner, it is ignited instantaneously. However, in this case, if the fire was extinguished, there was a risk that the combustible gas blown from the processing burner would fill the exhaust hood.
[0005]
In such an automated preform automatic processing device, basically, even if unburned combustible gas flows into the exhaust hood at the maximum flow rate, the exhaust flow rate is set so that the gas concentration does not exceed the explosion limit. Is designed, and when it flows out of the exhaust hood, it is detected by the combustible gas detector and the combustible gas supply line is shut off from the beginning, but the unburned combustible gas flows out There is a possibility of accidents beyond prediction, and it is dangerous. If an accident occurs, there is a high possibility that it will be a major accident, resulting in a large industrial loss.
[0006]
[Problems to be solved by the invention]
Because of this danger, it has been considered substantially difficult to automate the entire glass lathe machining process of the preform.
Therefore, the problem of the present invention is that it is possible to re-ignite instantly even if the fire is extinguished, and there is no risk of gas leakage even when re-ignition fails, and a safe preform automatic processing method and automatic It is to provide a processing apparatus.
[0007]
[Means for Solving the Problems]
The inventors of the present invention have focused on the importance of a pilot fire, and have repeated trial research on complete automation of the glass lathe machining process by improving the ignition mechanism, and have developed an automatic machining apparatus that is practically desirable.
That is, the method for automatically processing a preform according to the present invention is such that, in automatic processing of a preform using a glass lathe, the flame is always monitored by a flame detector, and when an extinguishing of the flame is detected, an electrical ignition device If the reignition fails automatically, the supply of flammable gas and combustion-supporting gas to the preform processing burner is stopped, and the preform processing is performed from the shutoff valve that stops the supply of both gases. The inside of the conduit leading to the burner is purged with nitrogen gas.
[0008]
An automatic preform processing apparatus according to the present invention is an automatic processing apparatus provided in a glass lathe used for processing a preform, and is a seed fire burner , a flame detection apparatus for the seed fire burner , and the flame detection When the device detects fire extinguishing of the fire, the fire igniter automatically reignites the fire for the fire, and the flammable gas and the combustion-supporting gas to the preform processing burner when the fire fails to reignite Is shut off by closing the shutoff valve, and the inside of the conduit from the shutoff valve to the processing burner is purged with nitrogen gas.
In addition, it is preferable to use an ultraviolet phototube for the flame detector.
[0009]
The present invention proposes an automatic preform processing method and apparatus capable of automatically and safely processing a preform, and in particular, provides a safety mechanism that ensures stable combustion of a processing burner. .
That is, the burner is always monitored with a flame detection device, and when a fire is extinguished, it is automatically reignited using a spark plug or the like. When reignition fails, the supply of combustible gas (hydrogen gas) and combustion-supporting gas (oxygen gas) is stopped, and the inside of the conduit from this shut-off valve to the processing burner is purged with nitrogen gas. It has a technical feature in that it has a mechanism for expelling stagnant unburned combustible gas and preventing accidents due to leakage of combustible gas.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS.
FIG. 1 is a schematic view showing an example of the automatic processing apparatus of the present invention. FIG. 2 is a schematic diagram showing a state of the control system of the automatic machining apparatus of the present invention, and FIG. 3 is a control signal flow diagram for monitoring the automatic machining of the apparatus.
The automatic processing apparatus of the present invention re-ignites the seed fire burner 10 when at least the glass lathe 1 detects a seed fire burner 10 , a seed fire flame detection apparatus 2 , and the flame detection apparatus 2 detects the extinction of the seed fire. When the combustion of the seed-fire automatic ignition device and the processing burner 3 is stopped, the supply of the combustible gas and the combustion-supporting gas is stopped by closing the shutoff valve, and the inside of the conduit from the shutoff valve to the processing burner 3 is stopped. Is purged with nitrogen gas.
The preform 4 is held while being rotated by the scroll chuck 5 of the glass lathe 1, and is heated by the processing burner 3 installed on the burner base 6. The seed fire is constantly monitored by the flame detection device 2, and when the fire is extinguished, it is instantly reignited by a spark plug 7 provided as a seed fire automatic ignition device. During processing, the outer diameter of the preform 4 is measured by the outer diameter measuring device 8. An exhaust hood 9 is provided above the glass lathe 1 to exhaust combustion exhaust gas.
[0011]
The spark plug 7 is attached in the vicinity of the seed fire burner 10 using hydrogen gas as fuel, and the seed fire burner 10 is ignited by the spark. In order to detect the flame of the ignited seed flame, a flame detection device 2 having a built-in ultraviolet phototube (UV detector tube) is attached toward the seed fire. When the flame detection device 2 detects that the seed flame burner 10 has become non-flame, the signal transmitted from the flame detection device 2 is processed by the computer 11 and transmitted to the igniter 12 to activate the spark plug 7. Then, the spark is blown and the ignition burner 10 is re-ignited.
The processing burner 3 is supplied with hydrogen gas and oxygen gas for combustion from the respective conduits 13 and ignited by a seed fire. When the spark plug 7 fails to relight the pilot flame, the signal from the flame detecting device 2 detects this is processed in the computer 11, the shut-off valve 15 of the conduit 13 leading to the working burner 3 by shut-off valve control unit 14 is Closed. At the same time, the shutoff valve 16 is opened, purge nitrogen gas (inert gas) is supplied into the conduit 13, and hydrogen gas and oxygen gas staying in the conduit 13 are discharged outside the tube, and an explosion occurs due to leakage of combustible gas. Accidents are prevented in advance. The MFC in the figure is a mass flow controller that adjusts the gas flow rate. Reference numeral 17 denotes a manual valve that is manually opened and closed.
FIG. 3 is a control signal flow diagram for monitoring the automatic machining at this time.
[0012]
In the automatic processing apparatus of the present invention, it is important to reliably ignite and burn the seed fire in the seed fire burner 10. As a method for igniting the seed fire burner 10, any of the conventionally known methods can be adopted. However, as an automatic ignition device used in the present invention, a fire extinguishing signal is received from the flame detection device when the seed fire is extinguished. An electrical ignition means that can automatically reignite electrically using a spark plug or the like is advantageous.
[0013]
Flame detection means for detecting the seed flame can detect ultraviolet rays, visible rays, infrared rays, etc. radiated from the flame, or can easily detect the presence or absence of a flame from the flame temperature, electrical conductivity, etc. is there. Hereinafter, these flame detection means will be described in detail.
As an apparatus using an ultraviolet phototube (UV phototube), there is a type that detects ultraviolet rays emitted from a flame by a small ultravision (model C7035A1064, manufactured by Yamatake Honeywell).
[0014]
As a type for detecting infrared rays emitted from a flame, there is an apparatus using a PbS (lead sulfide) phototube cell, for example, a red sulfide cell (model C7015, manufactured by Yamatake Honeywell). In this case, it is necessary to detect only infrared rays emitted from the flame. Since the intensity of the infrared rays radiated from the flame fluctuates, when a DC voltage is applied to the PbS cell, a pulsating current proportional to the intensity of the infrared radiation flows. When this pulsating current flows, it indicates that a flame exists, and when the pulsating current stops flowing, it indicates that the fire is extinguished.
Further, as a type for detecting visible to infrared rays emitted from a flame, there is an apparatus using a CdS (cadmium sulfide) phototube, for example, a cadmium sulfide cell (model C554A, manufactured by Yamatake Honeywell). This apparatus creates a red hot state by installing a nichrome wire or the like in a flame, and detects visible to infrared rays emitted therefrom.
[0015]
As an apparatus using a fiber type optical sensor, for example, an apparatus using a fiber photoelectric switch (model E3X-A11-8, manufactured by OMRON) is mentioned. A glass rod having a diameter of about 3 mm is attached to the fiber photoelectric switch. The tip of the is installed in a flame to detect light emitted from the red-hot tip.
Moreover, fire extinguishing can be detected by measuring the temperature of a flame using a thermocouple or a radiation thermometer. In this case, since the ignition temperature of hydrogen is 571 ° C., it is determined that the fire is extinguished when the measured temperature becomes 571 ° C. or lower, and the combustible gas line and the combustion-supporting gas line are shut off.
[0016]
Furthermore, fire extinguishing can be detected by monitoring the flame conductivity with a flame rod. When the flame rod is brought into contact with the flame, current flows between the burner flame and the flame rod due to the conductivity of the flame. When the fire is extinguished, the current is cut off and the fire extinguishing state can be detected.
Of these detection means, one means or a combination of two or more means may be used to obtain high safety. However, in the case of an oxyhydrogen flame, it can be detected with sufficient reliability only by ultraviolet rays, and this ultraviolet ray detection method is practical and industrially advantageous.
[0017]
【Example】
Example 1
The preform was attached to a glass lathe and the preform was stretched by an automatic computer program. In processing by an automatic program, the processing burner is ignited at the start of stretching, the fire is extinguished at the end of stretching, the quality of the shape is inspected by an outer diameter measuring machine, and if there is no problem, flame polishing is started. At this time, the processing burner is ignited twice or more in a series of processing steps such that the processing burner is ignited again and extinguished when the flame polishing is completed.
Upon ignition from the seed flame to the processing burner, the flame ignites explosively, so the flame of the seed flame may disappear instantaneously. However, even if the process proceeds with the seed flame extinguished, the flame detection device detects the flame of the seed flame when switching to the next process, and the spark plug and the seed flame burner are instructed by the computer based on this signal. A spark is made between the nichrome wire provided near the tip of the steel and the ignition fire burner is automatically reignited instantly. If reignited immediately, automatic processing of the preform proceeds with an automatic program built into the computer. On the other hand, as shown in FIG. 3, if no flame is confirmed during the spark for 10 seconds, the lines of flammable gas and flammable gas are shut off, and then the shutoff valve is instantaneously switched to the burner. The inside line was purged with nitrogen gas, and at the same time, the driving part of the glass lathe was stopped.
In this way, even if ignition fails, the interlock operates instantly, and it has been possible to prevent unburned hydrogen gas from leaking from the processing burner.
[0018]
(Comparative Example 1)
A conventional apparatus is shown in FIG. A processing burner 3 and a seed fire burner 10 are installed on the burner base 6, and hydrogen gas as a combustible gas is constantly supplied to the seed fire burner 10 and burned. The flow rate of hydrogen to the seed fire burner 10 is about several liters / minute, and is easily affected by the blast and the surrounding air at the time of ignition of the burner and the pressure fluctuation of the hydrogen supply source. These factors often cause the fire 18 to disappear. When the automatic program starts in a state where the seed flame 18 is extinguished, the combustible gas and the combustion-supporting gas are supplied to the processing burner 3 and are released from the burner without being burned, causing an accident. Therefore, in order to prevent such a situation, even when performing automatic processing, at least when igniting the burner, it was checked with human eyes.
Thus, in the past, monitoring by human eyes was indispensable from the viewpoint of safety.
[0019]
【The invention's effect】
The automatic processing apparatus of the present invention constantly monitors the seed fire, and at the time of fire extinguishing the fire, instantly reignites with the automatic ignition device, and even if the reignition fails, the combustible gas and the combustible gas By blocking the flow and at the same time purging the conduit from the shut-off valve to the burner with nitrogen gas, it was possible to prevent leakage of combustible gas and combustion-supporting gas.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an example of an automatic processing apparatus of the present invention.
FIG. 2 is a schematic diagram showing the state of the control system of the automatic machining apparatus of the present invention.
FIG. 3 is a control signal flow diagram for monitoring automatic processing of the automatic processing apparatus of the present invention.
FIG. 4 is a schematic view showing a conventional processing apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Glass lathe 2 ... Flame detection apparatus 3 ... Processing burner 4 ... Preform 5 ... Scroll chuck 6 ... Burner stand 7 ... Spark plug 8 ... Outer diameter measuring device 9 ... Exhaust hood 10 ... Seed fire burner 11 ... Computer 12 ... igniter 13 ... conduit 14 ... shut-off valve controller 15 ... shut-off valve 16 ... shut-off valve 17 ... manual valve 18 ... fire

Claims (3)

In automatic processing of optical fiber preforms using a glass lathe, the flame of the burner is constantly monitored by a flame detector, and when a fire of the flame is detected, it is automatically reignited by an electrical ignition device , When ignition fails, supply of flammable gas and combustion-supporting gas to the preform processing burner is stopped, and the inside of the conduit from the shutoff valve that stops both gas supply to the preform processing burner is filled with nitrogen gas. A method for automatically processing preforms for optical fibers, characterized by purging . An automatic processing apparatus provided in a glass lathe that is used for processing a preform for optical fibers, seeds fire burner, a flame detection device of the burner for seed fire, the extinguishing the pilot flame by the flame detection device Auto-ignition device that re-ignites the seed burner when detected, and shuts off the supply of flammable gas and combustion-supporting gas to the preform processing burner when re-ignition fails. And an optical fiber preform automatic processing apparatus having a mechanism for purging the inside of a conduit from the shut-off valve to the preform processing burner with nitrogen gas. The automatic processing apparatus for an optical fiber preform according to claim 2, wherein the flame detection device uses an ultraviolet phototube .

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